Studer Innotec RCC-02, RCC-03 user manual Adaptation to the Batterie

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RCC

You can now adapt your installation to the source which it is connected to.

Max. current of the AC source (power-sharing) {1107}.

In case of using the Xtender on a public grid, it is actually the value of the circuit breaker on the source side (fuse or breaker).

In a building, this value lies generally between 8 and 16A.

In the case of a shorepower or of a camping terminal, it lies between 2 and 6A.

In case of using the Xtender on a genset, you can divide the genset power by the operating voltage (for instance for a genset of 3500VA, or 3500W, and 230V you get 3500/230=15.2).

Caution: the powers given on the gensets are often overestimated compared to their real performances. To obtain a useable value it is necessary to multiply this result by 0.6 or 0.7 (in that case 15.2*0.7=10.64).

Press the key SET to modify the value of this parameter (it appears in reverse video). By means of the keys “arrow upwards” and “arrow downwards” change the value to adapt it to your source and validate your setting with the key SET (OK).

ADAPTATION TO THE BATTERIE

Charge current {1138}

In order that your Xtender manages the best possible the energy stored in your batteries and that it charges them optimally, it is necessary to indicate the current which they can be charged with. You will find this value in the technical data provided by your batteries manufacturer.

In the case of lead-acid batteries, one generally uses one tenth or one fifth of the battery capacity value.

For instance for a 500Ah battery: 500/10=50A to 500/5=100A.

The basic display is this one:

Press 3 times the key « arrow downwards » to display the following screen:

If you go overpass this screen you can come back to it by means of the key « arrow upwards »

Press the key SET to access to the settings.

With the key “arrow downwards”, access the menu “Battery and charger cycle”.

Press the key SET to access this menu.

You are now going to set the charge current for the batteries: Press the key SET to modify the value of this parameter (it appears in reverse video). With the keys “arrow upwards” and “arrow downwards” change the value to adapt your battery and validate your setting with the key SET (OK).

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Contents Studer Innotec Rue des Casernes CH 1950 Sion Studer Innotec Table of contents Maximum current of the AC source power sharing RCC Studer Innotec Foreword ConventionsProduct Recycling Your RESELLER’ Contact Details Studer Innotec Contact DetailsLimitation of Responsability WarrantySafety Instructions Acceptance of the Software Licence and UpdatesStuder Innotec SD Card Controls and IndicatorsIntroduction Models ConcernedSeries Connection ConnectionRCC-02 RCC-03 DimensionsAdjustment of the Language Quick Start GuideAdaptation to the Source Adaptation to the Batterie Activation of the Function SMART-BOOST Basic Displays Activating and Deactivating the Combi Xtender Adjustment of the BACK-LIGHTING Adjustment of the RCC Remote ControlAdjustment of Date 5002 and Time Adjustment of the ContrastDuration of the back-lighting Backup of statisticsLoading the Xtender configurations Backup of remote control configurationsBackup of Xtender configurations Loading the remote control configurationsInformation on the Operating Mode of the Installation Display of the Parallel and THREE-PHASE Systems Event History Alarm LOW Battery VoltageStop Battery Voltage TOO LOW Stop High Battery VoltageStop Overtemperature Error Incorrect Input FrequencyError Input Voltage TOO High Error Input Voltage TOO LOWStored Events Message Power Sharing Exceeded Transfer ProhibitedError Voltage AT AC OUT Error Phase not DefinedAdjustment of the Combi Xtender Authorised inverter Basic configurationsMaximum current of the AC source power sharing LockingAuthorised transfer Automatic restartAuthorised charger Smart boost authorisedRestore default configurations Battery cycle and chargerRCC Studer Innotec Charge current Temperature correction coefficientBattery maintenance voltage floating Force passage to floating modeEqualization phase Absorption phaseDuration of equalization Equalization before absorption phaseEqualization current Equalization voltageEnd of equalization activated by the current Inverter configurationsStandby level Output voltageCombi configurations Inverter-Charger Configurations for auxiliary contacts 1 and 2 1201 Switching mode 1202 Combination of events mode 1497Simple functions Contacts activated by an event 1455 Battery undervoltage alarm 1226Battery overvoltage 1227 Temporal restrictions 1203Contacts activated by the battery voltage 1245 Dynamic compensation of the thresholds 1288 Contacts activated by inverter power or smart boost 1257Deactivate if the battery is in floating mode 1516 Contacts activated with set schedules 1269Phase integral mode Extended functionsMulti Xtender Remote Controls Information on the SystemXtender Updates Updating ProcessCompatibility USE of a Limited Power Source Application ExamplesGénéral USE INVERTER, Charger with Grid Load Shedding of the Second Priority Loads USE to Increase the Power on AN Existing InstallationAnnexes Annexe 1 List of Configuration InterdependenciesRCC Studer Innotec RCC

RCC-03, RCC-02 specifications

Studer Innotec, a renowned Swiss company in the field of power electronics, has made significant strides with its range of battery management systems, particularly the RCC-02 and RCC-03 models. These units are renowned for their cutting-edge technologies, impressive features, and superior performance in managing energy systems for both off-grid and hybrid applications.

The RCC-02 and RCC-03 Remote Control Displays provide end-users with an intuitive interface to monitor and control their energy systems seamlessly. With a clear and easy-to-read display, these units offer real-time data, allowing users to view essential information such as battery voltage, current, and state of charge. This vital information empowers users to make informed decisions regarding energy consumption and system management.

One of the standout features of the RCC-02 and RCC-03 models is their compatibility with a wide range of Studer Innotec products, including inverters and battery chargers. This versatility ensures seamless integration into existing systems, making it an ideal choice for both new installations and upgrades of existing systems.

Both models incorporate advanced communication technologies such as RS-232 and CAN-bus, allowing for easy data logging and system monitoring. This connectivity not only ensures that the user has access to real-time data but also enables remote monitoring and diagnostics, significantly enhancing the overall user experience.

Another characteristic that sets the RCC-02 and RCC-03 apart is their robust design. These units are engineered to withstand the harsh conditions often found in off-grid environments, ensuring reliability and durability over an extended lifespan. The thoughtful design also includes user-friendly controls, making it easy to configure settings and manage system parameters for a wide array of applications.

Energy efficiency is paramount in today's energy-conscious world, and the RCC-02 and RCC-03 are designed to optimize battery usage. By providing timely information about battery status and energy flow, these units assist users in maximizing the lifespan of their batteries and ensuring that their energy resources are used effectively.

In summary, Studer Innotec’s RCC-02 and RCC-03 Remote Control Displays are essential components for anyone looking to harness the power of reliable battery management systems. With their advanced technologies, user-friendly interfaces, and robust construction, they represent the cutting edge of energy management in both off-grid and hybrid applications. Whether for residential, commercial, or industrial use, these units deliver efficiency, reliability, and peace of mind to users.
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