VE Bus Smart Dongle Victron Energy Instruction Manual
- June 1, 2024
- victron energy
Table of Contents
- VE Bus Smart Dongle Victron Energy
- Product Information
- Product Usage Instructions
- General description
- Charge disconnect
- Basic installation
- controlling DC loads and chargers
- Installation
- system examples
- Basic system
- System with an alternator
- Operation
- Updating the firmware
- FAQS
- Read User Manual Online (PDF format)
- Download This Manual (PDF format)
VE Bus Smart Dongle Victron Energy
Product Information
Technical Specifications
- Product: VE.Bus BMS V2
- Model: V2
- Revision: 05 – 01/2024
Product Usage Instructions
General Description
The VE.Bus BMS V2 is equipped with a pre-alarm feature that triggers when there is an imminent cell undervoltage. The default setting is 3.1V per cell, which can be adjusted between 2.85V and 3.15V per cell on the battery. There is a minimum delay of 30 seconds between the pre-alarm and load disconnect. Please note that the pre-alarm does not trigger notifications on the GX device or VRM.
Safety Precautions
It is important to follow safety precautions when using the VE.Bus BMS V2 to ensure proper operation and prevent any accidents. Refer to the safety precautions section in the user manual fordetailed guidelines.
Operation
Important Warning: Follow the instructions provided in the user manual for safe and effective operation of the VE.Bus BMS V2.
LED Indications: Refer to the user manual for a detailed explanation of the LED indications and their meanings.
Updating the Firmware
Using VRM: Follow the steps outlined in the user manual to update the firmware remotely using VRM.
Using VictronConnect: Utilize VictronConnect to update the firmware of the VE.Bus BMS V2. Refer to the manual for detailed instructions.
General description
The VE.Bus BMS V2 is a battery management system (BMS) for Victron Energy Lithium Battery Smart batteries available with a nominal voltage of 12.8V or 25.6V in various capacities. This is the safest of the mainstream lithium battery types. They can be connected in series, parallel and series/parallel so that a battery bank can be built for system voltages of 12V, 24V or 48V. Up to four 12.8V batteries or two 25.6V batteries can be connected in series. A total of 20 batteries can be connected, resulting in energy storage of up to 84kWh in a 12V system or up to 102kWh in a 24V and 48V system.
Protects each individual cell of a Victron Lithium Battery Smart (LiFePO₄) battery
Each individual cell of a LiFePO₄ battery must be protected against under- and
overvoltage, as well as low and high temperature. This is exactly what the
VE.Bus BMS V2 does in combination with the battery’s BTV module, which
provides appropriate signals to the BMS.
The Victron Lithium Battery 12.8V & 25.6V Smart have integrated Balancing,
Temperature and Voltage control (acronym: BTV) and connect to the VE.Bus BMS
V2 with two M8 circular connector cord sets. The BTVs of several batteries can
be daisy chained. Please see our Lithium Battery Smart product page for
details.
Depending on the signals from the battery, the BMS will:
- Generate a pre-alarm signal to warn of an imminent cell undervoltage.
- Shut down or disconnect loads in case of cell undervoltage.
- Turn off the inverter of VE.Bus inverter/chargers in case of cell undervoltage.
- Reduce the charge current in case of cell overvoltage or overtemperature of VE.Bus inverter/chargers or VE.Bus inverters.
- Shut down or disconnect battery chargers in case of cell overvoltage or overtemperature.
Pre-alarm
The pre-alarm output is normally free floating and becomes high in case of imminent cell undervoltage. It is set by default at 3.1V per cell and is adjustable on the battery between 2.85V and 3.15V per cell. The minimum delay between pre-alarm and load disconnect is 30 seconds. Note that the pre-alarm does not generate a notification on the GX device and therefore not on VRM either.
Load disconnect
The Load disconnect output is normally high and becomes free floating in case of cell undervoltage. The Load disconnect output can be used to control:
- The remote on/off terminal of a load.
- The remote on/off terminal of an electronic load switch like a BatteryProtect (preferred low power consumption solution).
Charge disconnect
The Charge disconnect output is normally high and becomes free floating in case of cell over voltage or over temperature. The Charge disconnect output can be used to control:
- The remote on/off terminal of a charger, like an AC charger, DC-DC charger or solar charger.
- A Cyrix-Li-Charge relay.
- A Cyrix-Li-ct Battery Combiner.
LED indicators
The BMS has the following LED indications:
- Status LED (blue): Lights once every 10 seconds when the Multi is switched on to indicate BMS info frames are being sent. When the Multi is off, either due to a low cell/remote off or just switched off by means off the front panel switch, the BMS goes into low power mode but continues to send BMS info frames (with a slightly longer interval between them). In this mode the BMS status led does not light up to conserve energy. If the BMS is stuck in the bootloader, the status LED will flash rapidly. This can happen, for example, after an interrupted firmware update (to fix this, restart the update on VictronConnect or via VRM).
- Cell voltage above 4V LED (red): Lights when the Charge disconnect output is low because of cell overvoltage or overtemperature.
- Cell voltage above 2.8V LED (blue): Lights when the Load disconnect output is high and the battery cell voltages are above 2.8V.
Connectivity and communication with GX device
- On/off/charger-only control of VE.Bus products via a GX device.
- GX DVCC control of solar chargers. There is no need to install an BatteryProtect or Cyrix-Li-Charge to control solar chargers via the BMS like the VE.Bus BMS V1 does.
Has separate power input and output connections for GX devices
- The GX-Pow output supplies GX power from either the battery or from the Aux-In input, whichever voltage is higher.
- An AC-DC adapter (not included) or other power supply connected to the Aux-In input will ensure that the GX device is powered as long as that Aux power is available, even if the battery is low, for example, due to an error the battery is in under voltage and the inverter/charger is switched off. This allows the system to be diagnosed remotely (assuming the Internet is still available), even when (almost) everything else is turned off. See the Technical specifications [22] for the required power rating of an AC-DC adapter.
• The GX-Pow output supplies GX power from either the battery or from the
Aux-In input, whichever voltage is higher.
• An AC-DC adapter (not included) or other power supply connected to the Aux-
In input will ensure that the GX device is powered as long as that Aux power
is available, even if the battery is low, for example, due to an error the
battery is in under voltage and the inverter/charger is switched off. This
allows the system to be diagnosed remotely (assuming the Internet is still
available), even when (almost) everything else is turned off. See the
Technical specifications [22] for the required power rating of an AC-DC
adapter.
True remote on/off terminal
- The VE.Bus BMS V2 needs to remain connected to the battery positive in order to be able to keep the Multi in low power mode even when AC input on the Multi is available (Multi will stop inverting/charging, close the transfer switch and indicate a low battery error on the status LEDs). In comparison, disconnecting the battery positive of the VE.Bus BMS V1 only really turns the Multi off when no AC input is available.
Safety precautions
- Installation must strictly follow the national safety regulations in compliance with the enclosure, installation, creepage, clearance, casualty, markings and segregation requirements of the end-use application.
- Installation must be performed by qualified and trained installers only.
- Carefully study the product manuals of all connected devices before installing them.
- Switch off the system and check for hazardous voltages before altering any connection.
- Do not open the lithium battery.
- Do not discharge a new lithium battery before it has been fully charged first.
- Charge a lithium battery only within the specified limits.
- Do not mount the lithium battery upside down or on its sides.
- Check if the lithium battery has been damaged during transport.
What’s in the box?
The following items are in the box
- 1x VE.Bus BMS V2
- 1x Mains detector
- 1x 0.3m RJ45 UTP cable
- Piece of Velcro adhesive hook and loop tape
Note that the DC power cable to power the BMS is not included. Use any 1-wire cable with at least 0.75mm2 (AWG 16) and a 1A inline fuse.
What’s in the box
Basic installation
- Connect the battery BMS cables to the BMS. For multiple batteries, see the Battery BMS cable connections [6] chapter. Be sure to read and follow the installation instructions in the Lithium Battery Smart manual.
- Connect the inverter/charger or inverter positive and negative cables to the battery. Make sure it has been updated to the most recent firmware version. For more information, see the Minimal VE.Bus firmware [5] chapter.
- Connect the battery positive via the red power cable with the fuse to the BMS “Battery+” terminal.
- Connect the VE.Bus port of the Inverter/charger or inverter to the “MultiPlus/Quattro” port of the BMS using the included RJ45 cable.
- In case of a new style MultiPlus 12/1600/70, new style MultiPlus 12/2000/80, MultiPlus-II or Quattro-II, don’t install the mains detector. For more information, see the Mains detector [7] chapter.
Note that the BMS does not have a battery negative connection. This is because the BMS obtains battery negative from the VE.Bus. As such, the BMS cannot be used without a VE.Bus Inverter/charger or a VE.Bus inverter.
Minimal VE.Bus firmware
Before connecting the BMS to the system, the VE.Bus firmware of all
inverter/chargers or inverters used in the system needs to be updated to the
latest firmware version (version xxxx489 or above).
If the inverter/charger firmware is between version xxxx415 and xxxx489, the
“VE.Bus BMS” or “ESS” assistant must be installed in the inverter/charger.
If the inverter/chargers or inverters have a VE.Bus firmware version below
xxxx415, the BMS will generate a VE.Bus error 15
(VE.Bus combination error). This error indicates that the VE.Bus products or
firmware versions cannot be combined. If it is not possible to update the
inverter/chargers or inverters to a VE.Bus firmware version xxxx415 or higher
the VE.Bus BMS V2 cannot be used.
Battery BMS cable connections
In the case of several batteries in parallel and/or series configuration, the
BMS cables should be connected in series (daisy-chained), and the first and
last BMS cable should be connected to the BMS.
If the BMS cables are too short, they can be extended with extension cables,
the M8 circular connector Male/Female 3 pole cables.
Mains detector
The mains detector is not required for the new style MultiPlus 12/1600/70 and MultiPlus 12/2000/80, MultiPlus-II, Quattro-II and inverter models. In this case, these chapters can be skipped, and the mains detector should be disposed of.
The purpose of the mains detector is to restart the inverter/charger when the
AC supply becomes available in case the BMS has shut down the inverter/charger
due to low cell voltage (so that it can recharge the battery).
In systems consisting of several units configured for parallel, three-phase,
or split-phase operation, the mains detector should be wired in the master or
leader unit only.
In the case of a MultiPlus, only use one AC wire pair, and in the case of a
Quattro, use both wire pairs.
controlling DC loads and chargers
DC load control
DC loads with remote on/off terminals:
DC loads must be switched off or disconnected to prevent cell undervoltage.
The Load disconnect output of the BMS can be used for this purpose. The Load
disconnect output is normally high (= battery voltage). It becomes free-
floating (= open circuit) in case of an impending cell undervoltage (no
internal pull down to limit residual current consumption in case of low cell
voltage).
DC loads with a remote on/off terminal that switches the load on when the
terminal is pulled high (to battery plus) and switches it off when the
terminal is left free-floating, can be controlled directly with the BMS Load
disconnect output.
DC loads with a remote on/off terminal that switches the load on when the
terminal is pulled low (to battery minus) and switches it off when the
terminal is left free-floating, can be controlled with the BMS Load disconnect
output via an Inverting remote on/off cable.
Note: please check the residual current of the load when in the off state. After low cell voltage shutdown, a capacity reserve of approximately 1Ah per 100Ah battery capacity is left in the battery. For example, a residual current of 10mA can already damage a 200Ah battery if the system is left in a discharged state for more than eight days.
Disconnecting a DC load via a BatteryProtect:
Use a BatteryProtect for DC loads that do not have a remote on/off terminal or for switching groups of DC loads off. A BatteryProtect will disconnect the DC load when:
- Its input voltage (= battery voltage) has decreased below a preset value.
- Its remote on/off H terminal becomes free floating (usually high). This signal is provided by the Load disconnect output
(wired to the remote on/off H terminal of the BatteryProtect) of the VE.Bus BMS V2. See the wiring example System with a BatteryProtect and a solar charger [14].
DC charge control
Controlling inverter/chargers, solar chargers and other battery chargers
In the event of high cell voltage or low temperature, battery charging must be stopped to protect the battery cells. Depending on the system, chargers are either controlled via DVCC or must be controlled via their remote on/off terminals and the Charge disconnect output of the VE.Bus BMS V2.
- In systems with a GX device, you must enable DVCC to ensure that the solar chargers and other DVCC-compatible devices only charge when they should. See DVCC operation with VE.Bus BMS V2 [9] for details.
- In systems without a GX device, the BMS Charge disconnect output must control the solar charger and other chargers, either via remote on/off, a BatteryProtect or a Cyrix-Li-Charge. See Charger control via Charge disconnect [9] for details.
DVCC operation with VE.Bus BMS V2
DVCC (Distributed Voltage and Current Control) allows a GX device to control
compatible devices such as solar chargers, Inverter RS, Multi RS or Multis.
In order for the GX device to control the solar chargers, Inverter RS or Multi
RS in a system with a VE.Bus BMS V2, DVCC must be enabled. These chargers are
controlled by setting their maximum charge current limit to zero when the
VE.Bus BMS V2 requests that charging should stop.
Note that the presence of a VE.Bus BMS V2 does not control the charge voltage of the solar chargers, Inverter RS, Multi RS or a Multi.
- In an ESS system, the Multi controls the charging voltage of the solar chargers, Inverter RS and Multi RS using the configuration made with VE.Configure or VictronConnect. In other words: The charge algorythm must be configured in the Multi.
- In a non-ESS (off-grid) system, the solar chargers, Inverter RS, Multi RS and Multi follow their own internal charge algorithm. Here, all devices must be set to the appropriate lithium charge algorithm.
AC chargers and smaller Phoenix inverters are not (yet) controlled by the GX device, and therefore you still need to wire signal wiring (via ATC aka Charge disconnect) to control such devices.
Charger control via Charge disconnect
Chargers that are not DVCC compatible or installed in systems without a GX device can be controlled via the VE.Bus BMS V2 Charge disconnect output, provided the chargers have a remote on/off port.
The Charge disconnect output, normally high (equal to battery voltage), must be connected to the H terminal of the charger’s remote on/off connector. At high cell voltage or low temperature, the Charge disconnect output becomes free-floating and pulls the charger’s remote on/off H terminal low (to battery minus), stopping the charge.
For battery chargers with a remote terminal that activates the charger when
the terminal is pulled low (to battery minus) and deactivates when the
terminal is left free floating, the Inverting remote on-off cable can be used.
Alternatively, a Cyrix-Li-Charge relay can be used. The Cyrix-Li-Charge relay
is a unidirectional combiner that inserts between a battery charger and the
lithium battery. It will engage only when charge voltage from a battery
charger is present on its charge-side terminal. A control terminal connects to
the Charge disconnect output of the BMS.
Charging with an alternator
Alternator charging can be controlled either with a DC-DC charger such as the
Orion-Tr Smart, or with a SolidSwitch 104 when controlling an external
alternator regulator like the Balmar MC-614.
Both devices are then also controlled by the BMS Charge disconnect output
wired to the Orion-Tr Smart or SolidSwitch 104 remote on/off H terminal. See
System with an alternator [16]
Remote on/off terminal
The BMS remote on/off terminal can be used to turn the entire system on and
off while the BMS remains connected to battery positive, which keeps the
inverter in low power (discharging and charging not allowed) mode even if it
is still connected to AC In.
The remote H and L terminals switch the system on when:
- Contact is made between the remote H terminal and L terminal, for example, via the wire bridge or a switch.
- Contact is made between the remote connector H terminal and battery positive.
- Contact is made between the remote connector L terminal and battery negative.
A typical application is switching off the system when a predetermined state of charge (SoC) is reached in a BMV. Its relay then operates the remote on/off terminal of the BMS. Note that at least the wire loop between pins L and H must be plugged in, so that the VE.Bus BMS V2 can switch on.
GX device
For solar chargers, Inverter RS, Multi RS or Multis to be controlled by the BMS via a GX device, the following requirements should be met:
- The GX device Venus OS firmware must be version 2.80 or above.
Installation
- Connect the GX device VE.Bus port to the Remote panel port on the BMS via an RJ45 cable (not included). Note that this is different from the former VE.Bus BMS V1, which allowed only the connection of a Digital Multi Control. The VE.Bus BMS V2 allows to connect a GX device, a VE.Bus Smart dongle or a Digital Multi Control.
- Connect the GX device “power +” terminal to the GX-Pow terminal of the BMS and connect the GX device “power -” terminal to the negative terminal of the battery.
- Connect the positive wire of an (optional) AC-DC power supply to the AUX-in terminal of the BMS and connect the negative wire to the negative battery terminal. Note that the AC-DC power supply is optional and most likely not needed in off-grid installations such as boats or RVs.
- Perform a VE.Bus re-detect system action on the GX device. This action is available in the inverter/charger menu on the GX device.
The functionality of the GX-Pow and Aux-In terminals:
- The GX-Pow output supplies GX power from either the battery or from the Aux-In input, whichever voltage is higher.
- An AC-DC adapter (not supplied) or other power supply connected to the Aux-In input ensures that the GX device is also powered during a low cell state as long as that aux power is available.
The GX device is powered by the GX-Pow terminal. The GX-Pow terminal is normally battery-powered via the Battery+ terminal. In the event of a low cell voltage, this connection would not be available, leaving the GX device without power. However, when another power supply (i.e. a grid-connected AC-DC power supply) is connected to the Aux-In, the GX-Pow connection will continue to power the GX device, allowing the system to remain accessible despite low cell voltage, for example, to remotely diagnosis the system.
Connecting a Digital Multi Control or a VE.Bus Smart dongle
A VE.Bus Smart dongle or Digital Multi Control (DMC) must be connected to the Remote panel port of the BMS. Both have on/off/charger-only control of the inverter/charger. It is also possible to connect the Phoenix Inverter Control panel in case a Phoenix VE.Bus inverter is used.
Note that in systems containing a Digital Multi Control and a GX device or a
VE.Bus Smart dongle at the same time, on/off/charger-only control of the
inverter/charger is only possible via the Digital Multi Control.
For example, the VE.Bus Smart dongle, Digital Multi Control and the GX device
can all be connected simultaneously to the Remote panel port. However, in this
scenario, on/off/charger-only control of the inverter/charger via the GX
device and VE.Bus dongle is disabled. Since inverter/charger control is
disabled, the GX device or VE.Bus Smart dongle can also be connected to the
MultiPlus/Quattro port of the BMS for easy wiring.
system examples
The system with a GX device, on/off switch and pre-alarm circuit
System with a SmartShunt, BatteryProtect and solar charger
Basic system
System with an alternator
Three-phase system with a Digital Multi Control
Operation
Important warning
Lithium batteries are expensive and can be damaged due to over-discharge or
over charge. Damage due to over discharge can occur if small loads (such as:
alarm systems, relays, standby current of certain loads, back current drain of
battery chargers
or charge regulators) slowly discharge the battery when the system is not in
use. In case of any doubt about possible residual current draw, isolate the
battery by opening the battery switch, pulling the battery fuse(s) or
disconnecting the battery plus when the system is not in use.
A residual discharge current is especially dangerous if the system has been
discharged completely and a low cell voltage shutdown has occurred. After
shutdown due to low cell voltage, a capacity reserve of approximately 1Ah per
100Ah battery capacity is left in the battery. The battery will be damaged if
the remaining capacity reserve is drawn from the battery. A residual current
of 10mA for example may damage a 200Ah battery if the system is left in
discharged state for more than 8 days.
The shutdown due to low cell voltage by the BMS should always be used as a
last resort to be on the safe side at all times. We recommend not letting it
get that far in the first place and instead shutting down the system
automatically based on a defined state of charge so that there is enough
reserve capacity in the battery. For an inverter/charger, for example, this
can be done via the VE.Configure setting ‘shut-down on SoC’. It is even easier
with a BMV, whose relay can control the remote on/off port of the BMS via an
adjustable SoC value.
LED indications
LED | Colour | Behaviour | Meaning |
---|
Status
| ****
Blue
| Off| BMS is off
Lights shortly approximately once every 10 seconds.| ****
BMS is operating normally.
Flashes rapidly at approximately 15 times per second.| ****
The BMS is stuck in boot loader mode due to a faulty application.
Cell > 2.8V
| ****
Blue
| ****
Off
| Low cell voltage.
The BMS has switched the DC loads and the inverter off.
Charge the battery or connect an AC supply to the inverter/charger. Once the battery voltage has increased sufficiently, the DC loads and inverter will be switched on again.
On| Cell voltage within normal range.
Cell > 4V
| ****
Red
| Off| Cell voltage and temperature within normal range.
On
| High cell voltage or high temperature. The BMS has switched off the chargers.
Check for a faulty charger and/or reduce battery temperature. Once the battery voltage and/or temperature have been sufficiently reduced, the BMS will switch the chargers back on.
Updating the firmware
Updating the VE.Bus BMS V2 firmware can be carried out in two different ways:
-
Via VRM : Remote firmware update: This functionality requires the device to be updated by connecting it to a GX device
(Cerbo GX, Ekrano GX or other). -
Update using VictronConnect or VEFlash (part of the VE Configuration tools for VE.Bus Products): This requires an MK3 USB interface. Please note that updating the firmware using VictronConnect or VEFlash requires either an Android phone, a PC or an Apple computer with macOS. Unfortunately, this is not possible with an iOS device.
Notes on firmware updating in general
- Newer is not always better.
- If it isn’t broken, don’t fix it.
- Be sure to read the changelog before starting the update process. The changelog can be downloaded from Victron Professional.
Therefore, use this feature with caution. Our main advice is not to update a running system unless there are problems with it or if a new feature included in the firmware is required for the installation. A firmware update should always be carried out for a new installation.
What firmware version do I have?
The firmware version is visible on the VictronConnect Product info page of the installed MultiPlus/Quattro and in VRM under Device List → Firmware Update.
Updating the firmware using VRM: Remote firmware update
The comprehensive procedure for performing a firmware update remotely via VRM,
known as VRM: Remote firmware update, is carefully described in a separate
manual and can be viewed here.
Additional notes
- Some warnings will appear before the update starts. Please read these carefully and take note of them. You have to confirm each of them. Do not update if you do not fully understand the terms.
- Do not perform the update when the GX device is powered by the inverter/charger. During the update, the inverter/charger is briefly switched off and on again.
- It is not possible to update the VE.Bus V2 in case there is also a Digital Multi Control connected to the VE.Bus network.
updating the firmware using VictronConnect
o perform a firmware update via VictronConnect, it requires an MK3 USB interface, which connects to the VE.Bus network via either an Android phone/tablet, a Windows PC or an Apple computer with macOS. Unfortunately, this is not possible with an Apple iOS device.
Step-by-step
- In VictronConnect, open the VE.Bus inverter/charger that is connected to the MK3 interface, and tap on the cog wheel icon to get to the Settings page.
- Since the settings are password protected, you need to enter the password in order to enable the settings. Please contact your installer or Victron distributor for the password.
- On the Settings page, tap on the three vertical dots.
- Tap on Product info to get to the Product info page.
- On the Product info page it will tell you if an update is available for VE.Bus BMS v2.
- Tap Update to go to the firmware library, then tap the firmware file you want to use.
- Tap on Update.
- On the next screen, read the warning. Once you fully understand the implications, tap OK to start the firmware update.
- Keep the VictronConnect app open while the update is in progress.
- Once the update has been performed, the product information page will automatically reappear. Check whether the current firmware number is displayed.
technical specifications VE.Bus BMS V2
General
General
Operating temperature| -20 to +50°C 0 – 120°F
Humidity| Max. 95% (non-condensing)
Protection grade| IP20
Enclosure
Enclosure
Material| ABS
Colour| Matt black with a blue sticker
Weight| 120gr
Dimension (h x w x d)| 23.8mm x 94.5mm x 105.5mm
Standards
Standards
Safety| EN 60950
Emission| EN 61000-6-3, EN 55014-1
Immunity| EN 61000-6-2, EN 61000-6-1, EN 55014-2
Automotive| EN 50498
External AC-DC adapter
External AC-DC adapter
Min. power rating| 1A@12V – If the nominal output voltage is > battery voltage, the AC-DC adapter takes over the power supply of the GX device.
Appendix
Dimensions VE.Bus BMS V2
VE.Bus BMS V2 compared to VE.Bus BMS V1
This table highlights the differences between the VE.Bus BMS V2 compared to it’s predecessor, the VE.Bus BMS V1.
FAQS
How do I adjust the pre-alarm voltage on the VE.Bus BMS V2?
The pre-alarm voltage can be adjusted between 2.85V and 3.15V per cell on the battery. Refer to the general description section in the user manual for detailed instructions.
Can I receive notifications for pre-alarms on the GX device or VRM?
No, the pre-alarm does not trigger notifications on the GX device or VRM. It is important to monitor the system closely for any alerts.
I have disconnected the VE.Bus BMS V2, my inverter charger will not switch on; why?
If the inverter/charger cannot find the BMS, it will go into an emergency mode. In this mode, the inverter/charger will charge the batteries with a maximum of 5A, up to 12, 24 or 48V (depending on the system voltage). While the inverter/charger is in this mode, only the Mains on
The batteries are empty, and the inverter/charger will not start to charge; how to get the system up and running again?
Connect a small battery charger, for example, a 5A charger, and wait for the battery voltage to get back up to 12, 24 or 48V (depending on the system voltage).
What happens with the inverter/charger when the BMS gives a low cell voltage signal?
The inverter/charger will be set to charger only mode, and the batteries are charged when an AC input is available. Should AC not be available, the inverter/charger is off.
What happens with the inverter/charger when the BMS gives a high cell voltage signal?
The high cell voltage signal will only be given when there are unbalanced cells. The inverter/charger will switch to bulk and starts charging with a reduced charge current. This allows the balancing system in the batteries to re-balance the cel
What does it mean when the BMS displays a VE.Bus Error 15?
With VE.Bus firmware versions below version xxxx415 the VE.Bus BMS V2 will generate a VE.Bus Error 15, VE.Bus combination error. This error indicates that the VE.Bus products or firmware versions cannot be combined. Resolution: Update the inverter/ charger to a firmware version xxxx415 or higher, if available.
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