Fronius Fronius Agilo Outdoor 75.0-3 / 100.0-3 Operating Instruction [EN]

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Fronius Agilo Outdoor

75.0-3 / 100.0-3

Operating Instructions

Grid-connected inverter

42,0426,0163,EN 007-06082015

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Dear reader,

Introduction Thank you for the trust you have placed in our company and congratulations on buying this

high-quality Fronius product. These instructions will help you familiarise yourself with the product. Reading the instructions carefully will enable you to learn about the many different features it has to offer. This will allow you to make full use of its advantages.

Please also note the safety rules to ensure greater safety when using the product. Careful handling of the product will repay you with years of safe and reliable operation. These are essential prerequisites for excellent results.

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Contents

Safety rules ................................................................................................................................................ 7

General information 11

Protection of people and equipment .......................................................................................................... 13

Safety.................................................................................................................................................... 13

Protection of people and equipment ..................................................................................................... 13

Galvanic (electrical) isolation ................................................................................................................ 13

Monitoring the grid ................................................................................................................................ 13

Warning notices on the device.............................................................................................................. 14

Proper use ................................................................................................................................................. 16

Proper use ............................................................................................................................................ 16

Application area ................................................................................................................................... 16

Regulations governing the photovoltaic system.................................................................................... 16

Functional principle .................................................................................................................................... 17

Functional principle ............................................................................................................................... 17

Cooling of the inverter through forced-air ventilation ............................................................................ 17

Power derating...................................................................................................................................... 17

Solar module grounding........................................................................................................................ 17

The inverter in a photovoltaic system ........................................................................................................ 18

General ................................................................................................................................................. 18

Tasks .................................................................................................................................................... 18

Converting DC to AC current ................................................................................................................ 18

Display function and data communication ............................................................................................ 18

System add-on...................................................................................................................................... 18

Description of the device............................................................................................................................ 19

Outside of inverter................................................................................................................................. 19

Inverter interior...................................................................................................................................... 20

Connection compartment...................................................................................................................... 21

Data communication area ..................................................................................................................... 22

Possible relay contact functions............................................................................................................ 25

Data communication and Solar Net ........................................................................................................... 26

Solar Net and data interface ................................................................................................................. 26

Overcurrent and undervoltage cut-out .................................................................................................. 26

Description of the 'Fronius Solar Net' LED............................................................................................ 26

Example ................................................................................................................................................ 27

Installation and commissioning 29

Choice of location ...................................................................................................................................... 31

General comments regarding choice of location...................................................................................31

Cabling into the inverter ........................................................................................................................ 31

Criteria influencing choice of location ................................................................................................... 32

Unsuitable locations.............................................................................................................................. 32

Transport.................................................................................................................................................... 33

Transport............................................................................................................................................... 33

Transporting by its lifting eyes using a crane........................................................................................ 33

Transporting by crane using pallet fork................................................................................................. 34

Transporting by forklift truck or lift truck ................................................................................................ 34

Positioning the inverter .............................................................................................................................. 35

Prerequisites ......................................................................................................................................... 35

Positioning the inverter ......................................................................................................................... 35

Notes regarding the air supply .............................................................................................................. 35

Connecting the inverter to the public grid (AC) .......................................................................................... 36

Monitoring the grid ................................................................................................................................ 36

Mains connections ................................................................................................................................ 36

Connecting aluminium cables ............................................................................................................... 36

Max. cross-section of AC cables........................................................................................................... 36

Safety.................................................................................................................................................... 37

Connecting the inverter to the public grid ............................................................................................. 37

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Connecting AC cables with a cable lug................................................................................................. 40

Maximum fuse rating on alternating current side .................................................................................. 40

Connecting an external AC supply for the inverter ...............................................................................40

Fitting and connecting optional overvoltage protection.............................................................................. 41

General ................................................................................................................................................. 41

Safety.................................................................................................................................................... 41

Fitting and connecting overvoltage protection on the DC side.............................................................. 41

Fitting and connecting overvoltage protection on the AC side.............................................................. 42

Fitting and connecting overvoltage protection for the AC- supply......................................................... 42

Connecting the DC cable to the inverter .................................................................................................... 44

General comments regarding solar modules ........................................................................................44

DC connections..................................................................................................................................... 44

Connecting aluminium cables ............................................................................................................... 44

Max. cross-section of DC cables .......................................................................................................... 44

Safety.................................................................................................................................................... 45

Connecting DC cables .......................................................................................................................... 45

Connecting DC cables with a cable lug ................................................................................................ 46

Fuse protection against polarity reversal of DC cables......................................................................... 46

Grounding the solar modules in the inverter .............................................................................................. 47

General ................................................................................................................................................. 47

Grounding the solar module to the negative pole via a fuse................................................................. 47

Safety.................................................................................................................................................... 48

Configuring the inverter for grounded solar modules............................................................................ 48

Grounding the solar module on the negative pole: inserting a fuse...................................................... 49

Closing the inverter .................................................................................................................................... 50

Closing the inverter ............................................................................................................................... 50

Using for the first time ................................................................................................................................ 52

Factory configuration ............................................................................................................................ 52

Using for the first time ........................................................................................................................... 52

Configuring the inverter for existing solar module grounding................................................................ 53

Operation 55

Controls and indicators .............................................................................................................................. 57

Controls and indicators ......................................................................................................................... 57

Display .................................................................................................................................................. 58

Symbols showing function key allocation.............................................................................................. 58

Monitoring and status LEDs.................................................................................................................. 59

Startup phase and feeding energy into the grid ......................................................................................... 60

Startup phase........................................................................................................................................ 60

Feeding energy into the grid ................................................................................................................. 60

Navigation at the menu level...................................................................................................................... 61

Activate display backlighting ................................................................................................................. 61

Automatic deactivation of display backlighting / change to display mode 'NOW' ................................. 61

Open menu level................................................................................................................................... 61

The display modes..................................................................................................................................... 62

The display modes................................................................................................................................ 62

Choosing a display mode...................................................................................................................... 62

Overview of display values ................................................................................................................... 63

Values in display mode 'NOW'................................................................................................................... 64

Choosing a display mode...................................................................................................................... 64

Values in display mode 'NOW'.............................................................................................................. 64

Values in display modes 'TODAY / YEAR / TOTAL' ..................................................................................66

Choose display mode 'TODAY / YEAR / TOTAL' ................................................................................. 66

Values in display modes 'TODAY / YEAR / TOTAL' ............................................................................. 66

The Setup menu ........................................................................................................................................ 69

Initial setting .......................................................................................................................................... 69

Accessing the setup menu.................................................................................................................... 69

Move up and down the menu items ...................................................................................................... 69

Menu items in the Set-up menu ................................................................................................................. 70

Standby................................................................................................................................................. 70

Contrast ................................................................................................................................................ 70

Backlighting........................................................................................................................................... 71

Language ............................................................................................................................................. 71

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Currency .............................................................................................................................................. 71

CO2 factor............................................................................................................................................. 71

Yield ...................................................................................................................................................... 72

DATCOM .............................................................................................................................................. 72

Device Info ............................................................................................................................................ 73

Device Status........................................................................................................................................ 74

Time ..................................................................................................................................................... 74

Status LT............................................................................................................................................... 75

Grid Status ............................................................................................................................................ 75

Fan test ................................................................................................................................................. 75

Version.................................................................................................................................................. 75

Setting and displaying the menu items ...................................................................................................... 76

Setting the menu items, general ........................................................................................................... 76

Exiting a menu item .............................................................................................................................. 77

Practical examples for setting and displaying menu items ................................................................... 77

Setting the display backlighting............................................................................................................. 77

Setting the currency and feed-in tariff ................................................................................................... 78

Setting the time and date ...................................................................................................................... 79

Switching the key lock on and off............................................................................................................... 81

General ................................................................................................................................................. 81

Switching the key lock on and off.......................................................................................................... 81

Troubleshooting and maintenance 83

Status diagnostics and troubleshooting ..................................................................................................... 85

Displaying status codes ........................................................................................................................ 85

Total failure of the display ..................................................................................................................... 85

Class 1 status codes............................................................................................................................. 85

Class 3 status codes............................................................................................................................. 87

Class 4 status codes............................................................................................................................. 88

Class 5 status codes............................................................................................................................. 93

Class 7 status codes............................................................................................................................. 96

Class 10 - 12 status codes.................................................................................................................... 98

Customer service .................................................................................................................................. 98

Maintenance .............................................................................................................................................. 99

Safety.................................................................................................................................................... 99

Maintenance guidelines ........................................................................................................................ 99

Replacement of components ................................................................................................................ 99

Opening the inverter for maintenance work .......................................................................................... 100

Operation in environments subject to heavy accumulations of dust ..................................................... 100

Replacing fuses ......................................................................................................................................... 101

Safety.................................................................................................................................................... 101

Replacing the reverse polarity protection fuse...................................................................................... 101

Appendix 105

Technical data............................................................................................................................................ 107

Fronius Agilo Outdoor 75.0-3................................................................................................................ 107

Fronius Agilo Outdoor 100.0-3.............................................................................................................. 108

Explanation of footnotes ....................................................................................................................... 109

Applicable standards and guidelines ......................................................................................................... 110

CE mark ................................................................................................................................................ 110

Parallel operation of in-plant generation systems ................................................................................. 110

Power failure ......................................................................................................................................... 110

Warranty terms and conditions, and disposal ............................................................................................ 111

Fronius manufacturer's warranty .......................................................................................................... 111

Disposal .......................................................................................................................

......................... 111

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Safety rules

Explanation of safety symbols

General

DANGER! Indicates immediate and real danger. If it is not avoided, death or se-

rious injury will result.

WARNING! Indicates a potentially dangerous situation. Death or serious injury may result if appropriate precautions are not taken.

CAUTION! Indicates a situation where damage or injury could occur. If it is not avoided, minor injury and/or damage to property may result.

NOTE! Indicates a risk of flawed results and possible damage to the equipment.

IMPORTANT! Indicates tips for correct operation and other particularly useful information.

It does not indicate a potentially damaging or dangerous situation.

If you see any of the symbols depicted in the "Safety rules" chapter, special care is required.

The device is manufactured using state-of-the-art technology and according to recognised safety standards. If used incorrectly or misused, however, it can cause

- injury or death to the operator or a third party,

- damage to the device and other material assets belonging to the operating company,

- inefficient operation of the device.

All persons involved in commissioning, maintaining and servicing the device must

- be suitably qualified,

- have knowledge of and experience in dealing with electrical installations and

- read and follow these operating instructions carefully.

The operating instructions must always be at hand wherever the device is being used. In addition to the operating instructions, attention must also be paid to any generally applicable and local regulations regarding accident prevention and environmental protection.

All safety and danger notices on the device

- must be kept in a legible state

- must not be damaged/marked

- must not be removed

- must not be covered, pasted or painted over.

For the location of the safety and danger notices on the device, refer to the section headed "General remarks" in the operating instructions for the device.

Before switching on the device, rectify any malfunctions that could compromise safety.

Your personal safety is at stake!

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Proper use

The device is to be used exclusively for its intended purpose.

Any use above and beyond this purpose is deemed improper. The manufacturer shall not be liable for any damage resulting from such improper use.

Proper use also includes:

- carefully reading and obeying all the instructions and all the safety and danger notices in the operating instructions

- performing all stipulated inspection and servicing work

- installation as specified in the operating instructions

The following guidelines should also be applied where relevant:

- Regulations of the company providing the mains power supply

- Instructions from the PV module manufacturer

Environmental conditions

Qualified service engineers

Operation or storage of the device outside the stipulated area will be deemed as "not in accordance with the intended purpose". The manufacturer shall not be held liable for any damage arising from such usage.

For exact information on permitted environmental conditions, please refer to the "Technical data" in the operating instructions.

The servicing information contained in these operating instructions is intended only for the use of qualified service engineers. An electric shock can be fatal. Do not perform any actions other than those described in the documentation. This applies even if you are qualified to do so.

All cables and leads must be secure, undamaged, insulated and adequately dimensioned. Loose connections, scorched, damaged or inadequately dimensioned cables and leads must be immediately repaired by authorised personnel.

Maintenance and repair work must only be carried out by authorised personnel.

It is impossible to guarantee that bought-in parts are designed and manufactured to meet the demands made of them, or that they satisfy safety requirements. Use only original spare parts (also applies to standard parts).

Do not carry out any modifications, alterations, etc. to the device without the manufacturer's consent.

Components that are not in perfect condition must be changed immediately.

Safety measures at the installation location

When installing devices with openings for cooling air, ensure that the cooling air can enter and exit unhindered through the air ducts. Only operate the charger in accordance with the degree of protection shown on the rating plate.

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Noise emission values

The inverter generates a maximum sound power level of < 80 dB(A) (ref. 1 pW) when operating under full load in accordance with IEC 62109-1:2010.

The device is cooled as quietly as possible with the aid of an electronic temperature control system, and depends on the amount of converted power, the ambient temperature, the level of soiling of the device, etc.

It is not possible to provide a workplace-related emission value for this device because the actual sound pressure level is heavily influenced by the installation situation, the power quality, the surrounding walls and the properties of the room in general.

EMC Device Classifications

EMC measures

Mains connection

Devices in emission class A:

- Are only designed for use in industrial settings

- Can cause line-bound and radiated interference in other areas

Devices in emission class B:

- Satisfy the emissions criteria for residential and industrial areas. This is also true for residential areas in which the energy is supplied from the public low-voltage mains.

EMC device classification as per the rating plate or technical data.

In certain cases, even though a device complies with the standard limit values for emissions, it may affect the application area for which it was designed (e.g. when there is sensitive equipment at the same location, or if the site where the device is installed is close to either radio or television receivers). If this is the case, then the operator is obliged to take appropriate action to rectify the situation.

High-performance devices (> 16 A) can affect the voltage quality on the mains network because they can feed powerful current into the main supply.

This may affect a number of types of device in terms of:

- connection restrictions

- criteria with regard to the maximum permissible mains impedance *)

- criteria with regard to the minimum short-circuit power requirement *)

Electrical installations

*) at the interface with the public mains supply

see Technical Data

In this case, the plant operator or the person using the device should check whether or not the device is allowed to be connected, where appropriate through discussion with the power supply company.

Electrical installations must only be set up set up to the relevant national and local standards and regulations.

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Protective measures against ESD

Danger of damage to electrical components from electrical discharge. Suitable measures should be taken to protect against ESD when replacing and installing components.

Safety measures in normal operation

Safety symbol

Disposal

Only operate the device if all safety devices are fully functional. If the safety devices are not fully functional, there is a risk of

- injury or death to the operator or a third party,

- damage to the device and other material assets belonging to the operator,

- inefficient operation of the device.

Any safety devices that are not functioning properly must be repaired by a suitably qualified engineer before the device is switched on.

Never bypass or disable safety devices.

Devices with the CE mark satisfy the essential requirements of the low-voltage and electromagnetic compatibility directives. Further details can be found in the appendix or the section headed "Technical data" in your documentation.

To comply with the European Directive 2002/96/EC on Waste Electrical and Electronic Equipment and its implementation as national law, electrical equipment that has reached the end of its life must be collected separately and returned to an approved recycling facility. Any device that you no longer require must either be returned to your dealer or given to one of the approved collection and recycling facilities in your area. Ignoring this European Directive may have potentially adverse affects on the environment and your health!

Data protection

The user is responsible for the safekeeping of any changes made to the factory settings. The manufacturer accepts no liability for any deleted personal settings.

The text and illustrations are all technically correct at the time of printing. We reserve the right to make changes. The contents of the operating instructions shall not provide the basis for any claims whatsoever on the part of the purchaser. If you have any suggestions for improvement, or can point out any mistakes that you have found in the instructions, we will be most grateful for your comments.

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General information

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Protection of people and equipment

Safety

Protection of people and equipment

Galvanic (electrical) isolation

Monitoring the grid

WARNING! If the equipment is used or tasks are carried out incorrectly, serious

injury or damage may result. Commissioning of the inverter may only be carried out by trained personnel in accordance with the technical regulations. It is essential that you read the "Safety Regulations" chapter before commissioning the equipment or carrying out maintenance work.

The inverter is constructed and operated in the safest possible way, both in terms of installation and operation.

The inverter fulfils the role of protecting people and equipment: a) through galvanic (electrical) isolation b) by monitoring the grid

The inverter has a 50/60 Hz three-phase transformer that provides electrical isolation between the DC side and the grid, thus guaranteeing the highest possible levels of safety.

In the event of abnormal grid conditions, the inverter shuts down immediately according to national standards and guidelines and stops feeding energy into the grid (e.g. in the event of grid disconnection, interrupts, etc.)

Grid monitoring is carried out by:

- monitoring the voltage

- monitoring the frequency

- using over/undervoltage relays (option, depends on country setup)

- monitoring the stand alone situation

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Warning notices on the device

There are warning notices and safety symbols on and in the inverter. These warning notices and safety symbols must not be removed or painted over. They warn against operating the device incorrectly, as this may result in serious injury and damage.

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Safety symbols:

Risk of serious injury and damage due to incorrect operation

Do not use the functions described here until you have fully read and understood the following documents:

- these operating instructions

- all the operating instructions for the system components of the photovoltaic system, especially the safety rules

Dangerous electrical voltage

Fronius Agilo 100.0-3

Discharging of the energy storage device is time-controlled

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Text of the warning notices:

WARNING!

An electric shock can be fatal. Make sure that both the input side and output side of the device are de-energised before opening the device. Wait for the capacitors to discharge (10 minutes).

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Proper use

Proper use The solar inverter is intended exclusively to convert direct current from solar modules into

alternating current and to feed this into the public grid. Utilisation not in accordance with the intended purpose comprises:

- utilisation for any other purpose or in any other manner

- making any modifications to the inverter that have not been expressly approved by Fronius

- the installation of parts that are not distributed or expressly approved by Fronius.

Fronius shall not be liable for any damage resulting from such action. No warranty claims will be entertained.

Proper use also includes:

- complying with all the instructions in the operating instructions

- performing all stipulated inspection and maintenance work

Application area The inverter has been developed exclusively for use in grid-connected photovoltaic sys-

tems; generating energy independently of the public grid is not possible.

Regulations governing the photovoltaic system

The inverter is designed to be connected and used exclusively in conjunction with solar modules. Use of the inverter with other DC generators (e.g. wind generators) is not permitted

When designing the photovoltaic system, ensure that all its components are operated within their permitted operating ranges at all times.

Observe all the measures recommended by the solar module manufacturer to ensure the lasting maintenance of the properties of the solar module.

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Functional principle

Cooling of the inverter through forced-air ventilation

The inverter operates fully automatically. The control module starts monitoring the grid voltage and frequency as soon as the solar modules produce enough energy after sunrise. When insolation has reached a sufficient level, the solar inverter will start to feed energy into the grid.

The inverter works in a way that ensures the maximum power possible is obtained from the solar modules. This is known as "Maximum Power Point Tracking" (MPPT).

As soon after dusk as the power available to feed into the mains falls below a sufficient level, the inverter disconnects from the mains supply. It retains all its settings and stored data.

Cooling of the inverter is performed by a forced-air ventilation system via a temperaturecontrolled radial fan. Air is sucked in from the front and fed, via a sealed duct, through the electronics compartment, before passing directly over the inductors and dissipating upwards. The sealed air duct prevents the electronics compartment from coming into contact with the ambient air. This approach largely prevents any contamination of the electronics compartment. The speed of the fan and temperature of the intake air are monitored.

The variable-speed, ball-bearing mounted fans in the inverter permit the following:

- optimum cooling of the inverter

- a higher level of efficiency

- cooler parts, therefore a longer service life

- lowest-possible energy consumption and noise levels

Power derating To protect the inverter if adequate heat dissipation is not possible, even with the fans run-

ning at full speed (e.g. when installed in containers without proper heat dissipation measures), the operation known as power derating takes place above an ambient temperature of approximately 45 °C.

Power derating briefly reduces the power of the inverter to prevent the temperature exceeding its permitted limit. The inverter remains operational for as long as possible without stopping.

Solar module grounding

The inverter is designed for use with non-grounded solar modules and those grounded on the negative pole. Grounding of the solar module on the negative pole is carried out inside the inverter via a fuse holder equipped with a corresponding fuse as required.

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The inverter in a photovoltaic system

General The solar inverter acts as a highly sophisticated link between the solar modules and the

public grid.

Tasks The main tasks of the inverter are as follows:

- converting DC to AC current

- fully automatic operational management

- display function and data communication

Converting DC to AC current

Display function and data communication

System add-on The inverter is able to accommodate a wide variety of system add-ons, such as:

The inverter converts the direct current created in the solar modules into alternating current. This alternating current is fed synchronously with the grid voltage into the in-house network or the public grid.

IMPORTANT! The inverter has been developed exclusively for use in grid-connected photovoltaic systems; generating energy independently of the public grid is not possible.

The display on the inverter acts as the interface between the inverter and the user. The display design is oriented towards simple operation and to making the system data available at all times.

The inverter has a range of basic functions for logging minimum and maximum values on a daily and total basis. The values are output on the display.

An extensive selection of data communication elements opens up numerous recording and visualisation options.

- a datalogger, to enable a PC to record and manage data from a photovoltaic system

- various large-format displays

- interfaces to transfer system data in a freely accessible format

- devices to combine and monitor solar module strings

The inverter is not designed to be used with optional plug-in cards. System add-ons must be installed in a separate housing.

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Description of the device

Outside of inverter

(7)

(6)

(5)

(4)

(10) (11)(8) (9)

(12)

(13)

(3)

(1) (2)

Item Description

(1) (2)

(3) Front base-cover (opposite: rear base-cover)

(4) DC main switch, lockable when switched off

(5) Door

(6) Control elements (display, buttons, monitoring and status LEDs)

(7) Exhaust air hood

(8) (9)

(10) (11)

(12) Air inlet grille

Mounting lug (front and rear)

Behind the front base-cover the forklift truck receptacle is located.

IMPORTANT! The door cannot be opened when the DC main switch is switched on.

Lifting eye for crane transport (front and rear, under the exhaust air hood)

(14) (15) (16)

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Inverter interior

Item Description

(13) Door handle (lockable)

(14) Right side panel (opposite: left side panel)

(15) (16)

Mounting lug (front and rear)

(1)

(2)

(3)

(4)

(5) (6)

(7)

(8)

Item Designation

(1) Fan

(behind the air inlet grille)

(2) Data communication area

(3) Fuse holder for operation with solar modules grounded to the negative pole:

DC- to PE

(4) 2-pin automatic circuit breaker

to protect the AC power supply

(5) 4-pin automatic circuit breaker

to protect the measuring lines on the grid side

(6) DC main switch

The DC main switch shaft is not fitted when the inverter is delivered.

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Connection compartment

(7) Connection area

(8) Door catch

(not shown)

(1)

(2)

(9)

(8)

(7)

(3)

(4)

Item Description

(1) DC+ connections

(2) DC- connections

(3) Openings for attaching the strain-relief clamps* for the DC+ cable

(4) Openings for attaching the strain-relief clamps* for the DC- cable

(5) Cable input opening with sliding cover and seal

(6) Openings for attaching the strain-relief clamps* for the AC cable

(7) Grounding terminal for AC cable

(8) AC power supply

(9) Mains connections L1, L2, L3 and N

* The strain-relief clamps and other installation and connection accessories are

part of the scope of supply of the inverter.

(6)

(5)

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Data communication area

(1) (2) (3) (4) (5) (6) (7) (10)(8) (9)

Item Description

(1) (2)

for future use

(3) Solar Net IN connection socket

'Fronius Solar Net' input, for connecting to other DATCOM components (e.g. inverter, sensor box, etc.)

(4) Solar Net OUT connection socket

'Fronius Solar Net' output, for connecting to other DATCOM components (e.g. inverter, sensor box, etc.)

(5) VSR connection socket

for connecting an external measuring and monitoring relay

The contact must be potential-free. Contact rating 24 V / 10 mA

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Item Description

(6) NO/alarm terminals

| S3 EXT 2 | 3 IN1 4 | 5 IN2 6 | 7 IN3 8 |

S3 - 2 EXT

for connecting an external NO contact, e.g. to isolate the device from the grid voltage using an AC contactor; connected using bracket when delivered.

3 - 4 IN1

for connecting and evaluating a floating alarm contact

5 -6 IN2

for connecting and evaluating a floating alarm contact

7 - 8 IN3

for connecting and evaluating a floating alarm contact

The contacts must be potential-free.

Contact rating 24 V / 10 mA Cable cross-section: 0.5 - 6 mm² Tightening torque of terminals: 0.8 - 1.6 Nm

(7) 'Solar Net' LED

shows the current status of the Fronius Solar Net

(8) Fuse F1 for switched-mode power supply, 4 A slow-blow

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Item Description

(9) Relay output terminals

| NC1 SC1 NO1 | NC2 SC2 NO2 |

NC1 NC for relay contact 1 SC1 Relay contact 1 NO1 NO for relay contact 1

NC2 NC for relay contact 2 SC2 Relay contact 2 NO2 NO for relay contact 2

Cable cross-section: 0.5 - 6 mm² Tightening torque of terminals: 0.8 - 1.6 Nm Max. continuous current: 16 A Switching load: 500 mW (10 V / 5 mA) Switching capacity: 16 A / 250 V (AC1) and 16 A / 30 V (DC1) The relay outputs are not protected.

Relay contacts can be assigned different functions in the Basic service menu. The access code 22742 must be entered to access the Basic service menu:

- Press the 'Menu' key

- Select 'Setup' mode

- Press the unassigned 'Esc' button five times

- Enter the access code 22742

- Select the 'Switch contact 1' or 'Switch contact 2' parameter

- Set the desired relay contact function

(10) F2 fuse, 4 A slow-blow

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Possible relay contact functions

Function Switch contact ac-

tivation criterion

Switch contact deactivation criteri-

Description

Off - Permanently OFF Function switched

off

On Permanently ON - Test function for NO/

alarm contact

AC Open AC contactor is open AC contactor is

closed

Fan On Cabinet fan in opera-

tion

> 40 °C max. internal tem-

perature >/= 40 °C

> 50 °C max. internal tem-

perature >/= 50 °C

Sig. Rel. NO/alarm contact

trips

Running Inverter feeding en-

ergy into the grid

Warning Defined warning sta-

tus codes

Cabinet fan not working

max. internal temperature </= 30 °C

max. internal temperature </= 40 °C

Error confirmation at the touch of a button

Inverter not feeding energy into the grid

Error confirmation at the touch of a button

No contactor error signal or AC grid

External ventilation / air conditioning can be activated

Status indicator / relay contact switches

Control of powered non-return valve

NO/alarm contact activation, when certain warning status codes occur at a specific frequency according to the 'Error-Counter' Service menu

Error Defined error status

codes

Error confirmation at the touch of a button

NO/alarm contact activation, when certain error status codes occur at a specific frequency according to the 'Error-Counter' Service menu

Activation = the NC for the relay contact opens, the NO closes

Deactivation = the NC for the relay contact closes, the NO opens

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Data communication and Solar Net

Solar Net and data interface

Overcurrent and undervoltage cutout

Fronius Solar Net was developed to make system add-ons flexible and capable of being used in a wide variety of different applications. Fronius Solar Net is a data network that enables more than one inverter to be linked up using system add-ons.

It is a bus system. A single cable is all that is required for one or more inverters to communicate with all the system add-ons.

Fronius Solar Net automatically recognises a wide variety of system add-ons.

In order to distinguish between several identical system add-ons, each one must be assigned a unique number.

Similarly, every inverter on the Fronius Solar Net must be assigned a unique number. Refer to the section entitled 'The Setup-Menu‘ for instructions on how to assign a unique number.

More detailed information on the individual system add-ons can be found in the relevant operating instructions or on the internet at http://www.fronius.com.

More detailed information on cabling DATCOM components can be found at http://www.fronius.com - Solar Electronics / Info & Support / Document downloads / Operating instructions / System monitoring / Fronius DATCOM cabling guide.

The data communications electronics have a cut-out function that interrupts the power supply in the Fronius Solar Net:

- in response to overcurrent, e.g. in the event of a short circuit

- in response to undervoltage

Description of the 'Fronius Solar Net' LED

The overcurrent and undervoltage cut-out does not depend on the current flow direction. If the Fronius Solar Net measures a current flow > 3 A or a voltage < 6.5 V, the power supply in the Fronius Solar Net is interrupted. The power supply is restored automatically.

The 'Fronius Solar Net' LED is on:

the power supply for data communication within the Fronius Solar Net is OK

The 'Fronius Solar Net' LED is off:

data communication error in the Fronius Solar Net

- Overcurrent (current flow > 3 A, e.g. resulting from a short circuit in the Fronius Solar Net)

- Undervoltage (not a short circuit, voltage in Fronius Solar Net < 6.5 V, e.g. if there are too many DATCOM components on the Fronius Solar Net and not enough electrical power is available)

In this case, power for the DATCOM components must be supplied by connecting an external power unit to one of the DATCOM components.

To detect the presence of an undervoltage, check some of the other DATCOM components as required.

Page 29

The 'Fronius Solar Net' LED flashes briefly every 5 seconds:

following a shutdown as the result of an overcurrent or undervoltage, the inverter attempts to restore the power supply to the Fronius Solar Net every 5 seconds while the fault persists.

Once the fault is rectified, power to the Fronius Solar Net will be restored within 5 seconds.

Example Recording and archiving of inverter data using Fronius Datalogger Web, data output on ex-

ternal display:

Fronius Agilo Outdoor

Fronius IG Plus

Display

Fronius Datalogger Web

12VDC 1A Class 2

12VDC

Output

Class 2

Input only max. 42V AC/6A US: Class 2 only

RS232

OUT

LAN

OUT

Fronius Public Display Box

OUT

= Endstecker

PC / Laptop

= Fronius Com Card

Captions: Fronius Solar Net data network with

- 1 Fronius Agilo Outdoor

- 1 Fronius IG Plus with a 'Fronius Com Card'

- 1 Fronius Datalogger Web with LAN interface for connecting to a PC/laptop

- 1 Fronius Public Display Box

- 1 external display

Communication between the individual components themselves is handled by Fronius Solar Net.

Page 30

Page 31

Installation and commissioning

Page 32

Page 33

Choice of location

General comments regarding choice of location

Cabling into the inverter

The inverter is primarily designed for installation outdoors. Provided there is sufficient ventilation, the inverter may also be used in an indoor environment.

The following points must also be taken into account in the choice of location:

- the cabling into the inverter,

- the specified bending radii of the cables,

- adequate bearing capacity per m² of floor for weight of the inverter: Fronius Agilo Outdoor 100.0-3 ... 806 kg Fronius Agilo Outdoor 75.0-3 ... 732 kg

IMPORTANT! The adequate bearing capacity of the floor must be ensured before introducing and setting up the inverter!

The AC cable, DC cable and the data communications cable, if required, can be fed into the inverter as follows:

a) b) c) Plan view

a) from below (e.g. via a cable duct or a false floor, maximum cable cross-section = 240

mm²)

b) from the side through the base c) from the rear through the base

Feeding the cabling through the base is only possible for cables with a cross-section of max. 120 mm².

Feeding the cabling from the rear is only possible for cables with a cross-section of max. 95 mm².

IMPORTANT! If AC cables, DC cables and data communication cables are fed together into the inverter, ensure adequate insulation is provided between the AC/DC cables and the data communication cables.

Page 34

Criteria influencing choice of location

Place on a solid, even. level and fire-resistant surface only.

Max. ambient temperatures: -25 °C; +50 °C

Can be used at altitudes of up to 2000 m

Maintain the following lateral clearances between the inverter and a wall:

450 mm

400 mm*

* Wall - left side of inverter:

min. 400 mm (to permit the door to be opened fully)

min. 50 mm (to open the door 90°)

** Wall - right side of inverter:

0 mm

200 mm**

Unsuitable locations

min. 200 mm (to permit the air inlet grille to be opened fully)

min. 80 mm (to open the air inlet grille 90°)

Two or more inverters can be placed side-by-side or back-to-back.

The airflow within the inverter is from the front to the top (cold air taken in at the front, hot air emitted out of the top).

Because of its degree of protection, the inverter is not susceptible to splash water from any direction.

Ideally, the inverter should be installed in a protected location, e.g., under a roof overhang.

Do not install the inverter:

- in areas in which a heavy build-up of dust containing conductive particles (e.g. iron chips) is likely

- where it can be exposed to ammonia, corrosive gasses, acids or salts (e.g., fertilizerstorage areas, vent openings of livestock stables, chemical plants, tanneries)

- in areas where there is an increased risk of damage from farm animals (horses, cattle, sheep, pigs, etc.)

Page 35

Transport

Transport The inverter weighs approx. 806 kg and can be transported as follows:

- by its lifting eyes, e.g. using a crane or other suitable lifting gear and tackle

- by its forklift truck receptacle, e.g. using a forklift truck, lift truck or crane in conjunction with pallet forks

Transporting by its lifting eyes using a crane

Transporting by its lifting eyes using a crane is only possible, when the exhaust air hood is dismantled .

WARNING! Falling equipment can cause serious or even fatal injury. When transporting the inverter using a crane

- always use all four of the lifting eyes provided for this purpose,

- the length of the lifting tackle (chain, rope, strap, etc.) must be chosen so that the angle between the lifting tackle and the horizontal is at least 60°.

min. 60°

Page 36

Transporting by crane using pallet fork

WARNING! Falling equipment can cause serious or even fatal injury. When

transporting the inverter using a crane and pallet fork

- the pallet fork must have a headroom of at least 1950 mm

- always insert the pallet fork into the forklift truck receptacle

- always insert the pallet fork completely into the forklift truck receptacle

- secure the inverter to prevent it slipping off the pallet fork

Remove the front and rear base covers from on the inverter before transporting it using a pallet fork, forklift truck or lift truck.

Transporting by forklift truck or lift truck

Remove the front base cover Remove the rear base cover

WARNING! Equipment that falls or topples over can cause serious or even fatal injury.

- always insert the fork into the forklift truck receptacle

- always insert the fork completely into the forklift truck receptacle

- secure the inverter to prevent it slipping off the fork or falling over

- avoid sudden changes in direction, braking or acceleration

Remove the front base-cover and the rear base-cover from the inverter before transporting it using a pallet fork, forklift truck or lift truck.

Removing the front base-cover Removing the rear base-cover

Page 37

Positioning the inverter

Prerequisites

Positioning the inverter

WARNING! Equipment that falls or topples over can cause serious or even fatal

injury.

- Place the inverter on a solid, level surface in such a way that it remains stable.

- Do not under any circumstances tip the inverter while it is being positioned.

Before positioning the inverter, clarify how the cables are going to be fed in. If it is not going to be possible to feed any cables into the inverter once it has been positioned, all the AC, DC and data communication cables must, before the inverter is put in place,

- be dimensioned accordingly,

- protrude at least 650 mm out of the floor.

CAUTION! Risk of cable damage as a result of shearing or bending. if any cables are protruding out of the floor, use a crane or forklift truck to lift the inverter over the cables and position the inverter in its desired location.

IMPORTANT! Ensure that any covers which were removed previously are refitted before the inverter is moved to its final position (e.g. fit the rear base-cover before positioning the inverter up against a wall).

Notes regarding the air supply

WARNING! Equipment that topples over can cause serious or even fatal injury.

- Place the inverter on a solid, level surface in such a way that it remains stable.

- Fix the inverter at the mounting lugs firmly to the ground.

Fixing material for fixing the inverter on the ground is not included with the inverter. The installer is responsible for the proper selection of dowels, screws, etc..

Transport the inverter to its location

Fit any covers that will no longer be accessible once the inverter is in its final position

Move the inverter into its final position

Adjust the inverter horizontally using the leveling feet.

The leveling feet are located at the bottom of the inverter, for better accessibility optionally remove the left and right base-cover.

Depending on the accessibility fix the inverter with suitable dowels and screws ideally

4 x at the mounting lugs on the floor.

If the inverter is positioned in a protected area, the air supply to the inverter must be at least 1200 m³/h (approx. 20 m³/min).

Page 38

Connecting the inverter to the public grid (AC)

Monitoring the grid

Mains connections

IMPORTANT! To provide the best possible grid monitoring, the resistance in the leads to

the mains connections should be as low as possible.

Legend:

NOTE! Ensure that the grid neutral conductor is grounded.

M10

L1 Phase conductor L2 Phase conductor L3 Phase conductor N Neutral conductor PE Ground conductor / grounding

Connecting aluminium cables

IMPORTANT! Only the following cables may be connected to V-type terminals:

- RE (round single-wire)

- RM (round multi-strand)

- SE (sector-shaped single-wire)

- SM (sector-shaped multi-strand)

- fine-core cables, in conjunction with ferrules only

Fine-core cables without ferrules may only be connected to the M10 threaded bolts of the mains connections using a suitable M10 cable lug; tightening torque = 18 Nm

Aluminium cables can be connected to the mains connections.

NOTE! When connecting aluminium cables:

- observe national and international guidelines regarding the connection of aluminium cables

- follow the instructions of the cable manufacturer

- check every year that the cables are securely attached in accordance with the specified torque.

Max. cross-section of AC cables

The max. cable cross-section of AC cables when feeding them in from below is 240 mm².

Page 39

Safety

WARNING! An electric shock can be fatal. Danger due to grid voltage and DC

voltage from solar modules that are exposed to light.

- Make sure that both the AC side and the DC side of the inverter are de-energised before carrying out any connection work.

- Only an authorised electrical engineer is permitted to connect this equipment to the public grid.

CAUTION! Risk of damage to the inverter as the result of incorrectly tightened cable connections. Incorrectly tightened cable connections can cause heat damage to the inverter that may result in a fire. When connecting AC and DC cables, ensure that all the cables are tightened to the inverter terminals with the specified torque.

CAUTION! Risk of damage to the inverter due to the ingress of moisture.

- Never open the inverter during rain.

- Do not establish any connections or carry out any maintenance work during rain.

Connecting the inverter to the public grid

NOTE! Ensure that the phases are connected in the right order: L1, L2, L3, N and

PE. After connecting the phases, check the rotary field of the grid using a rotary field measuring device. The inverter is designed for a clockwise rotary field.

IMPORTANT!

Minimum cable cross section for the ground conductor PE: 10 mm² für Copper wire 16 mm² für Aluminium wire

OFF

Page 40

- Feed the AC cable into the inverter, observing the bending radii specified by the cable manufacturer

- Strip sheath from AC cable

- Strip at least 20 mm of wire from phase

conductors L1 - L3, neutral conductor N and ground conductor PE

- Align phase conductors L1 - L3 and neutral conductor N with the grid connections according to the phase

- Push the AC terminal over the phase conductor, the neutral conductor and the ground conductor

- Push the AC terminal up and over the grid connection and the bare end of the cable

- Tighten the AC terminal: 5 mm Allen key

Tightening torque = 12 Nm

L1 L2 L3 N

- Place the insulation caps onto the grid connections

- Repeat the process for phase conductors L2 and L3 and the neutral conductor N

- Align the ground conductor PE with the grounding terminal

- Push the PE terminal up and over the grounding terminal and the bare end of the cable

- Tighten the PE terminal: 5 mm Allen key

Tightening torque = 12 Nm

Page 41

- Place the AC cable in the clamp of the strain-relief device

- Attach the clamps of the strain-relief

device to the rail

- Secure the AC cable with the clamps of the strain-relief device

NOTE! Different openings are available on the rail for attaching the clamps of the strain-relief device, depending on the cable routing.

e.g.:

A cable routed at an angle from the

bottom right - attach the clamp for the strain-relief device to positions 3 and 4

B cable routed at an angle from the

bottom left - attach the clamp for the strain-relief device to positions 1 and 2

C vertical cable routing - attach the

clamp for the strain-relief device to positions 5 and 6

Page 42

Connecting AC cables with a cable lug

Alternatively, an AC cable with a cable lug can be connected to the M10 threaded bolts on the mains connections in order to connect the AC cables to the V-type terminals.

NOTE! Ensure that the phases are connected in the right order: L1, L2, L3, N and PE. After connecting the phases, check the rotary field of the grid using a rotary field measuring device. The inverter is designed for a clockwise rotary field.

Maximum fuse rating on alternating current side

L1 L2 L3 N

M10

18 Nm

M10

Inverter Phases Nominal output Fuse protection

Fronius Agilo 75.0-3 3 100 kVA 3 x 200 A

Fronius Agilo 100.0-3 3 100 kVA 3 x 200 A

Connecting an external AC supply for the inverter

Procedure for connecting an external AC supply for the inverter (e.g. to provide an external supply to controllers or fans):

1 2

* If present, connect ground conductor to grounding terminal 9

Page 43

Fitting and connecting optional overvoltage protection

General Standard type II overvoltage protection can be fitted in the inverter as an option:

- for the DC side,

- for the AC side,

- for the external AC supply of the inverter.

DIN rails and passage openings to the AC and DC terminals for the cables are provided in the inverter for fitting overvoltage protection. The existing remote contacts on the overvoltage protection can be connected to the NO/ alarm contact terminals in the data communication area. In the event of a fault, the incoming signals can then be evaluated and shown on the display.

Overvoltage protection is not included in the scope of supply of the inverter. The engineer is responsible for the correct selection of the relevant overvoltage protection so as to comply with national and international regulations.

Safety

WARNING! Work that is carried out incorrectly can cause serious injury and dam-

age. Overvoltage protection must only ever be installed and connected by a qualified electrical installation engineer! Follow the safety rules! Make sure that both the AC side and the DC side of the inverter are de-energised before carrying out any installation or connection work.

Fitting and connecting overvoltage protection on the DC side

NOTE! Installing a Type I overvoltage protection device in the inverter is prohib-

ited.

IMPORTANT!

- Provide a separate grounding terminal for each overvoltage protection device

- Make sure that the cables have adequate insulation resistance.

Fit overvoltage protection to the DIN rail on the DC side according to the manufactur-

er's instructions

Fit a grounding terminal to the DIN rail on the DC side

Remove the 2 blank screw joints on the DC side

Insert 2 M20 screw joints from the inverter's accessories kit into the openings and se-

cure them with the hexagonal nuts of the blank screw joint

Prepare the cable:

- Strip the cable on the overvoltage protection side

- Fit the M10 cable lug on the DC connection side

Max. cable cross-section must comply with the instructions of the overvoltage protection manufacturer.

Open the M20 screw joints

Feed the cable through

Connect the cable to the overvoltage protection device according to the manufactur-

er's instructions

Page 44

Use the M10 hexagonal nut and the washer to connect the cable with the correct po-

larity at the central M10 threaded bolt of the relevant DC connection

Close the M20 screw joints

Connect the overvoltage protection to the grounding terminal

If available, connect the remote contacts of the overvoltage protection device with two

cables to the NO/alarm contact terminals in the data communication area

Fitting and connecting overvoltage protection on the AC side

IMPORTANT!

- Provide a separate grounding terminal for each overvoltage protection device

- Make sure that the cables have adequate insulation resistance.

Fit overvoltage protection to the DIN rail on the AC side according to the manufactur-

er's instructions

Fit a grounding terminal to the DIN rail on the AC side

Remove 3-4 blank screw joints on the AC side, depending on the overvoltage protec-

tion

Insert 3-4 M20 screw joints from the inverter's accessories kit into the openings and

secure them with the hexagonal nuts of the blank screw joint

Prepare the cable:

- Strip the cable on the overvoltage protection side

- Fit the M10 cable lug on the AC connection side

Max. cable cross-section must comply with the instructions of the overvoltage protection manufacturer.

Open the M20 screw joints

Feed the cable through

Connect the cable to the overvoltage protection device according to the manufactur-

er's instructions

Connect the cable to the upper part of the relevant AC connection in the correct phase

sequence Tightening torque = 18 Nm

Close the M20 screw joints

Connect the overvoltage protection to the grounding terminal

If available, connect the remote contacts of the overvoltage protection device with two

cables to the NO/alarm contact terminals in the data communication area

Fitting and connecting overvoltage protection for the AC- supply

IMPORTANT!

- Provide a separate grounding terminal for each overvoltage protection device

- Make sure that the cables have adequate insulation resistance.

Fit overvoltage protection to the DIN rail on the AC side according to the manufactur-

er's instructions

Fit a grounding terminal to the DIN rail

Strip the cable on both sides

Max. cable cross-section must comply with the instructions of the overvoltage protection manufacturer.

Connect cables L1 and N on the overvoltage protection device according to the man-

ufacturer's instructions

Page 45

Run the cable to the 2-pin automatic circuit breaker to safeguard the AC power supply

Connect cables L1 and N on the automatic circuit breaker in the correct phase se-

quence

Connect the overvoltage protection to the grounding terminal

If available, connect the remote contacts of the overvoltage protection device with two

cables to the NO/alarm contact terminals in the data communication area

Bind the cable with cable ties if necessary

Page 46

Connecting the DC cable to the inverter

General comments regarding solar modules

DC connections

To enable suitable solar modules to be chosen and to use the inverter as efficiently as possible, it is important to bear the following points in mind:

- If insolation is constant and the temperature is falling, the open circuit voltage of the solar modules will increase. The open circuit voltage must not exceed 950 V. If the open circuit voltage exceeds 950 V, the inverter will be destroyed and no warranty claims will be entertained.

- More exact values for dimensioning the solar modules can be provided by suitable calculation programs, like the Fronius Solar.configurator (which can be downloaded from www.fronius.com).

NOTE! Before connecting the solar modules, check:

- that the voltage specified by the manufacturer corresponds to the actual measured voltage.

- whether the solar modules need to be grounded.

M10 M10 M10 M10

30 mm

DC+ DC-

Connecting aluminium cables

IMPORTANT! Only the following cables may be connected to V-type terminals:

- RE (round single-wire)

- RM (round multi-strand)

- SE (sector-shaped single-wire)

- SM (sector-shaped multi-strand)

- fine-core cables, in conjunction with ferrules only

Fine-core cables without ferrules may only be connected to the M10 threaded bolts of the DC connections using a suitable M10 cable lug; tightening torque = 30 Nm

Aluminium cables can also be connected to the DC connections.

NOTE! When connecting aluminium cables:

- observe national and international guidelines regarding the connection of aluminium cables

- follow the instructions of the cable manufacturer

- Once a year, make sure that the cables are securely connected according to the specified torque.

Max. cross-section of DC cables

The DC connections on the inverter are designed for cables with a cross-section of max. 240 mm². With this maximum cross-section, 2 cables can be connected to each pole.

Page 47

Safety

WARNING! An electric shock can be fatal. Danger due to grid voltage and DC

voltage from solar modules that are exposed to light.

- Make sure that both the AC side and the DC side of the inverter are de-energised before carrying out any connection work.

- Only an authorised electrical engineer is permitted to connect this equipment to the public grid.

CAUTION! Risk of damage to the inverter as the result of incorrectly tightened terminals. Incorrectly tightened terminals can cause heat damage to the inverter that may result in a fire. When connecting AC and DC cables, ensure that all the terminals are tightened to the specified torque.

Connecting DC cables

Remove contact protectors

Feed the DC cable into the inverter, observing the bending radii specified by the cable

manufacturer

Strip at least 25 mm of insulation from the DC cable

Align the DC cable with the DC connections

DC+ DC-

- Push the DC terminal over the DC cable

- Push the DC terminal up and over the DC connection and the bare end of the cable

- Tighten the DC terminal: 6 mm Allen key

Tightening torque = 25 Nm

- Repeat this process for every DC cable

- Place the DC cable in the clamp of the

strain-relief device

- Attach the clamp of the strain-relief device to the rail

- Secure the DC cable with the clamp of the strain-relief device

- Repeat this process for every DC cable

Fit the contact protectors

NOTE! Different openings are available on the rail for attaching the clamps of the strain-relief device, depending on the cable routing.

Page 48

e.g.:

Connecting DC cables with a cable lug

A cable routed at an angle from the

bottom right - attach the clamp for the strain-relief device to positions 1 and 2

B cable routed at an angle from the

bottom left - attach the clamp for the strain-relief device to positions 3 and 4

C vertical cable routing - attach the

clamp for the strain-relief device to positions 5 and 6

Alternatively, a DC cable with a cable lug can be connected to the M10 threaded bolts on the DC connections in order to connect the DC cables to the V-type terminals.

NOTE! Ensure the polarity is correct when connecting the DC cables.

Fuse protection against polarity reversal of DC cables

2x DC+

2x DC-

M10

18 Nm

The inverter is fitted with a fuse to protect against any polarity reversal of the DC cables. The fuse will blow if the inverter is activated with the polarity of the DC cables reversed. Status code 307 "DC low" is shown on the display, even in the event of sufficient levels of insolation.

Should this occur, the reverse polarity protection fuse must be replaced as described under "Replacing fuses" in the "Troubleshooting and maintenance" section.

Page 49

Grounding the solar modules in the inverter

General Some manufacturers of solar modules stipulate that the module must be grounded.

Inside the inverter is a means for grounding solar modules to the negative pole via a fuse.

Locking ring for solar module grounding on the negative pole

Grounding the solar module to the negative pole via a fuse

(1) Solar module (2) Inverter

(1)

DC+

DC-

(3)

(2)

=~=

L1 L2

(3) Fuse

Fronius recommends the following fuse when grounding the solar module to the negative pole: nominal current rating 3 A / 1000 V, fuse dimensions 10 x 38 mm

IMPORTANT! Fuses for grounding the solar module are not part of the scope of supply of the inverter. If the manufacturer of the solar module stipulates that grounding is required, an appropriate fuse must be ordered separately

WARNING! An electric shock can be fatal. Danger of electric shock if the solar module is not grounded or is not grounded properly. To comply with IEC 62109-2, any grounding required by the manufacturer of the solar module within the inverter must only be carried out via the specified fuse.

Page 50

Safety

WARNING! An electric shock can be fatal. Danger due to DC voltage from solar

modules that are exposed to light. The inverter's insulation monitoring is deactivated when the solar modules are grounded.

- Ensure that grounded solar modules are designed so that they are isolated according to Protection Class II

- Place the relevant safety sticker in a clearly visible place on the photovoltaic system

- Configure the inverter so that a warning message is displayed if the fuse trips.

Warning sticker for solar module grounding

IMPORTANT! The warning sticker and the fuse for grounding the solar module

Warnung!

Ein elektrischer Schlag kann tödlich sein. Gefahr durch DC-Spannung von den Solarmodulen. Die Isolationsüberwachung des Wechselrichters ist deaktiviert. Die Solarmodule sind geerdet. VorArbeiten an der Photovoltaik-Anlage AC- und DC-Seite spannungsfrei schalten.

Warnung!

are not part of the scope of supply of the inverter and must be ordered separately.

Configuring the inverter for grounded solar modules

The inverter's insulation monitoring must be deactivated when the solar modules are grounded. At the second level of the Setup menu, the inverter must be configured so that when the grounding fuse trips, an error message is displayed or the inverter is switched off (according to the country setup). Access code 22742 must be entered in order to access the 2nd level of the Setup menu.

Page 51

Grounding the solar module on the negative pole: inserting a fuse

WARNING! An electric shock can be fatal. Danger due to DC voltage from solar

modules that are exposed to light. The DC main switch is only to be used to de-energise the power stage set. Grounding of the solar module on the negative pole remains in effect, even when the DC main switch is switched off. Do not under any circumstances touch DC+ or DC-.

1 2

Inserting the fuse grounds the solar modules on the negative pole.

Page 52

Closing the inverter

WARNING! An inadequate ground conductor connection can cause serious inju-

ry or damage. The screws on the air inlet grille and on the covers provide a suitable ground conductor connection for the housing; these screws must not under any circumstances be replaced by other screws that do not provide a reliable ground conductor connection.

Check that all covers and contact protection devices are fitted;

fit any covers and contact protection devices that are missing

Tightening torque = 3 Nm

NOTE! To avoid damaging the DC main switch, only close the door of the inverter once the switch itself is switched to the "OFF" position.

Page 53

2 3

Tightening torque = 3 Nm

Page 54

Using for the first time

Factory configuration

Using for the first time

The inverter is preconfigured in the factory. The language and the time must be set when the inverter is used for the first time.

Refer to the section in this manual entitled 'The Setup Menu' for the individual configuration options.

After connecting the DC cable to the inverter and the inverter to the grid (AC):

Insert covers and contact protection

Close and secure air inlet grilles

Close door

Turn the DC main switch to the - 1 - position

If the solar modules are producing enough voltage, the inverter will enter the startup phase. The inverter is about to start up automatically.

Once the inverter has completed its automatic startup, the operating state LED will show steady green.

Provided that energy continues to be fed into the grid, the operating state LED will remain steady green to confirm that the inverter is functioning correctly.

A window then appears for setting the language:

The time and the date must then be set:

Use the 'Up' and 'Down' keys to select

the desired language

Press the 'Enter' key to set the lan-

guage

The time is displayed (HH:MM:SS, 24-hour format), the hours field starts flashing.

Use the 'Up' and 'Down' keys to select

a value for the hour

Press the 'Enter' key

The minutes field starts flashing.

Repeats steps 7 and 8 for the minutes

and seconds until...

Page 55

the set time starts flashing.

Press the 'Enter' key

The time is applied and the date now appears (DD.MM.YYYY), the day field starts flashing.

Use the 'Up' and 'Down' keys to select

a value for the day

Press the 'Enter' key

The month field starts flashing.

Repeat steps 11 and 12 for the month

and the last 2 digits of the year until ...

the set date starts flashing.

Configuring the inverter for existing solar module grounding

Press the 'Enter' key

If setting of the language and the time are skipped by pressing the Back key and no settings are made during the setup, these two prompts appear again the next time the inverter is started.

NOTE! If the solar module is already grounded on the negative pole, the appropriate grounding method must be set in the 'Basic Service Menu' when the inverter is switched on. The access code 22742 must be entered in order to access the 'Basic Service Menu'.

Confirm any status codes that are displayed by pressing 'Enter'

Press the 'Menu' key

Press the unassigned 'Menu / Esc' key

5 times

Enter the access code 22742

The inverter is now in the 'Basic Service Menu' and the first parameter 'DC operating mode' is displayed.

Page 56

Grounding Mode

Use the 'Up' and 'Down' keys to select

the 'Grounding Mode' parameter

Press the 'Enter' key

'Grounding method' is displayed.

Press the 'Enter' key

The currently selected grounding method is displayed.

Off = un-grounded system (no solar module grounding) Factory setting

Use the 'up' or 'down' buttons to se-

lect the 'Negative' grounding method

Grounding Mode

Negative = solar module grounded on the negative pole:

Press the 'Enter' key

The 'Negative' grounding method is applied, 'Grounding method' and 'Grounding monitoring' are displayed.

To quit the 'Basic Service Menu',

press the 'Esc' key twice

Page 57

Operation

Page 58

Page 59

Controls and indicators

Item Description

(1) Display

for displaying values, settings and menus

(1)

(2)

(3)

(4)

(5) (6) (7) (8)

Monitoring and status LEDs

(2) General status LED (red)

lights when there is a status code on the display

(3) Startup LED (orange)

for displaying whether the inverter is in its startup phase or is on standby

(4) Operating state LED (green)

for displaying the operating state

Function keys - allocated different functions depending on the selection:

(5) 'Left/up' key

for navigating to the left and up

(6) 'Down/right' key

for navigating down and to the right

(7) 'Menu/Esc' key

for switching to the menu level for quitting the Setup menu

(8) 'Enter' key

for confirming a selection

Page 60

Display Power for the display comes from the mains voltage. The display is therefore available per-

manently.

IMPORTANT! The display on the inverter is not a calibrated measuring device. A slight inaccuracy of a few percent from the energy meter used by the energy supply company is intrinsic to the system. A calibrated meter will be needed to calculate the bills for the energy supply company.

Display modes

Parameter explanation

Display of values and units as well as status codes

Function key assignment

Display areas in display mode

Inverter no. | Storage sym. (**)

Symbols showing function key allocation

(*)

Display modes

Preceding menu items

Currently selected menu item

Next menu items

Function key assignment

Display areas in setup mode

(*) Scroll bar (**) INV no. = Inverter DATCOM number,

Save symbol - appears briefly while the selected values are being saved

The following symbols are displayed to indicate the function key assignments:

Navigate: left

Navigate: up

Increase value

Navigate: right

Navigate: down

Reduce value

Menu / Back

Enter

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Monitoring and status LEDs

(1) General status LED (red)

(2) Startup LED (orange)

(3) Operating state LED (green)

(1)

(2)

(3)

LED Colour Activity Explanation

(1) red lights up General status: the relevant status code is

shown on the display

Interruption while feeding energy into the grid

While error handling (the inverter waits for an acknowledgement or for an error to be rectified)

(2) orange lights up The inverter will enter its automatic startup or

self-test phase as soon after sunrise as the solar modules are delivering sufficient power

The inverter has been switched to standby mode in the setup menu = grid power feed operation switched off manually

The inverter software is being updated

(3) green lights up The LED lights up after the automatic startup

phase of the inverter, provided energy is being fed into the grid. The photovoltaic system is working properly.

A list of the relevant status codes, and causes and remedies can be found in the 'Status diagnosis and repair' section under 'Maintenance and service'.

Page 62

Startup phase and feeding energy into the grid

Startup phase Once it has been switched on automatically, the inverter carries out the following tests and

checks:

a) Self-test of all important inverter components - the inverter runs through a virtual

checklist

b) Synchronisation with the grid

c) Startup test

Before the inverter starts feeding energy into the grid, the grid conditions according to national regulations are tested. Depending on the country-specific regulations, the startup test can last just a few seconds or take several minutes.

During the startup phase:

- the operating state LED shows orange,

- the string 'warte...' (wait...) and the currently tested component are displayed, e.g.:

Feeding energy into the grid

- Once the tests have been completed the inverter starts feeding energy into the grid

- The display shows the current energy level that is being fed into the grid, e.g.:

- The operating state LED shows green, the inverter is working.

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Navigation at the menu level

Activate display backlighting

Automatic deactivation of display backlighting / change to display mode 'NOW'

Open menu level

Press any key

The display backlighting is activated.

The option remains in the setup menu to set the display backlighting so that it is on all the time or off all the time.

If no key is pressed for 2 minutes,

- the display backlighting switches off automatically and the inverter switches to display mode 'NOW' (assuming the display backlighting is set to automatic).

- The switchover to the 'NOW' display mode can happen from anywhere within the display modes or the Setup menu, with the exception of the 'Standby' menu item.

- The amount of energy currently fed in is displayed.

Press the 'Menu' key

'Menu' will appear on the display

The inverter is now at the menu level.

From the menu level

- the required display mode can be selected

- the Setup menu can be accessed

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The display modes

Choosing a display mode

The following display modes are available on the inverter:

Display mode 'NOW' ...... Displays real-time values

Display mode 'TODAY' ...... Displays values for energy fed into the grid today

Display mode 'YEAR' ...... Displays values for energy fed into the grid during

the current calendar year

Display mode 'TOTAL' ...... Displays values for energy fed into the grid since

the inverter was originally commissioned.

Open menu level

Use the 'left' and 'right' keys to select

the required display mode

Press the 'Enter' key

The first value of the selected display mode is displayed.

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Overview of display values

Display mode Unit Display value

'NOW' W Energy supplied

Day characteristic

V Three-phase AC grid voltage

A Three-phase AC output current

Hz AC grid frequency

V PV array voltage

A PV array current

°C Ambient temperature

rpm Fan speed

'TODAY' 'YEAR'

HH:MM

DD.MM

kWh / MWh Energy Supplied

Time

Date

Day characteristic ('TODAY')

'TOTAL' Currency Yield

g / kg CO2 saving

W Max. output power

V Max. three-phase AC grid voltage

V Max. PV array voltage

HH:MM Operating hours

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Values in display mode 'NOW'

Choosing a display mode

Values in display mode 'NOW'

First value in display mode 'NOW'

NOW

Choose display mode 'NOW'

The first value in display mode 'NOW' appears

Scroll to the next display value using

the 'Down' key

Scroll back up using the 'Up' key

AC Output Power

Power (in watts) currently being fed into the grid

Press the 'Enter' key to display the day characteristic.

Day characteristic

Displays a plot showing the power output during the day. The time axis is scaled automatically.

TODAY

Press the 'Back' key to remove the display

AC Grid Voltage

Phase voltage (Volt)

Press the 'Enter' key to display the string voltage.

String Voltage

displays the string voltage of each phase.

Press the 'Back' key to remove the display

AC Output Current

Phase current currently being fed into grid (Ampere)

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AC Grid Frequency

(Hertz)

PV Array Voltage

Voltage currently present on the solar modules (Volt)

PV Array Current

Current that is being supplied at present by the solar modules (Ampere)

Ambient Temperature

Temperature of the air sucked in to cool the inverter (°C)

Fan Speed

(rpm)

Time

If the time is changed on an inverter or a system add-on, it will also be changed in any other devices that are connected via Fronius Solar Net.

Date

If the date is changed on an inverter or a system add-on, it will also be changed in any other devices that are connected via Fronius Solar Net.

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Values in display modes 'TODAY / YEAR / TOTAL'

Choose display mode 'TODAY / YEAR / TOTAL'

First value in display mode 'TODAY'

First value in display mode 'YEAR'

Choose display mode 'TODAY' or

display mode 'YEAR' or display mode 'TOTAL'

The first value in the selected display mode appears.

Scroll to the next display value using

the 'Down' key

Scroll back up using the 'Up' key

Values in display modes 'TODAY / YEAR / TOTAL'

First value in display mode 'TOTAL'

Energy Supplied

Energy fed into the grid during the period in question (kWh / MWh)

Press the 'Enter' key to display the day characteristic (only in display mode 'TODAY')

Day characteristic

Displays a plot showing the power output during

NOW

TODAY

There may be discrepancies with values displayed on other measuring instruments because of differences in measuring methods. As far as adding up the energy fed in is concerned, the only binding display values are those produced by the calibrated measuring device provided by the electricity supply company.

the day. The time axis is scaled automatically.

Press the 'Back' key to remove the display

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Yield

Amount of money earned during the period in question (currency can be selected in the Setup menu)

Like the energy supplied figure, the yield figure may also exhibit discrepancies with other measured values.

The 'Setup Menu' section explains how to select a currency and charge rate. The factory setting depends on the respective country setup.

CO2 Savings

Amount by which CO2 emissions were reduced during the period in question (g / kg)

The value for CO2 savings depends on the power station facilities and corresponds to the CO2 emissions that would be released when generating the same amount of energy. The factory setting is 0.59 kg / kWh (source: DGS – Deutsche Gesellschaft für Sonnenenergie e.V. (German Society for Solar Energy)

Max. Output Power

Largest amount of power (W) fed into the gird during the period in question

Max. AC Grid Voltage

Highest AC grid voltage (V) measured during the period in question

Max. PV Array Voltage

Highest PV array voltage (V) measured during the period in question

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Operating Hours

Length of time the inverter has been working (HH:MM).

Although the inverter does not operate during the night, the data required for the Sensor Box option is logged and stored 24 hours a day.

IMPORTANT! A prerequisite for the correct display of day and year values is that the time is set correctly.

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The Setup menu

Initial setting After completing comissioning the inverter is pre-configured depending on the country set-

up.

The SETUP menu item allows the initial settings of the inverter to be changed easily to bring it in line, as closely as possible, with the preferences and requirements of the user.

Accessing the setup menu

Move up and down the menu items

'SETUP' menu level selected

'Standby' menu item

Switch to the menu level

(press the 'Menu' key)

Select 'Setup' mode using the 'Left' or

'Right' keys

Press the 'Enter' key

The first menu item in the Setup menu, 'Standby', is shown.

Example: 'Standby' menu item Example: 'Contrast' menu item

Accessing the setup menu

Use 'Up' and 'Down' keys to move between the available menu items

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Menu items in the Set-up menu

Standby Manual activation / deactivation of Standby mode

- No energy is fed into the grid.

- The Startup LED will show steady orange.

- In Standby mode, no other menu item at menu level can be accessed or adjusted.

- The automatic switchover into the 'NOW' display mode after 2 minutes of keyboard inactivity does not occur.

- Standby mode can only be terminated manually by pressing the 'Enter' key.

- Feeding energy into the grid can be resumed at any time (deactivate 'Standby').

Switching off Standby mode (manually switching off feeding energy into the grid):

Select the 'Standby' item

Press the 'Enter' key

'STANDBY' and 'ENTER' appear alternately on the display. Standby mode is now active. The Startup LED shows steady orange.

Resuming feeding energy into the grid:

'STANDBY' and 'ENTER' appear alternately on the display when in Standby mode.

Press the 'Enter' key to resume feeding energy into the grid

The 'Standby' menu item is displayed. At the same time, the inverter enters the startup phase. The operating state LED shows steady green when feeding energy into the grid has been resumed.

Contrast Adjusts contrast on the display.

Unit -

Setting range 0 - 10

Factory setting 5

Since the contrast is temperature-dependent, when the ambient conditions change it may be necessary to adjust the 'Contrast' menu item.

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Backlighting Initial setting for display backlighting

Unit -

Setting range AUTO / ON / OFF

Factory setting AUTO

AUTO: Display backlighting is activated by pressing any key. If no key

is pressed for 2 minutes, the display backlighting will go off again.

ON: The display backlighting remains permanently on when the in-

verter is switched on.

OFF: The display backlighting is permanently switched off.

IMPORTANT! The 'Backlight' menu item only relates to the backlighting of the display and the keys.

Language Setting the display language

Unit -

Display area German, English, French, Dutch, Italian, Spanish, Czech, Slo-

vak

Factory setting (depends on country setup)

Currency Sets the currency and charge rate for the energy fed into the grid

Unit -

Display area Currency/ feed-in tariff

Factory setting (depends on country setup)

CO2 factor Setting the CO2 reduction factor

Unit kg/kWh

Setting range 00.01 - 99.99

Factory setting 0.59 kg/kWh

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Yield Setting

- of an OFFSET value for the total energy display

- of a measuring offset factor for the day, year and total energy display

Setting range Meter deviation / meter unit of measurement / meter calibration

Meter deviation

Input of a value for the fed-in energy that will be added to the energy currently fed in (e.g. carry-over value when replacing an inverter)

Unit Wh

Setting range Five digits

Factory setting 0

Meter unit of measurement

Input of a unit (k..., M...)

Unit -

Setting range k / M

Factory setting -

Meter calibration

Input of a correction value to ensure that the value shown on the inverter display corresponds with the calibrated display on the electricity meter

Unit %

Setting range -5.0 - +5.0

Factory setting 0

DATCOM Checking data communications, entering the inverter number, protocol settings

Setting range Status / inverter number / protocol type

Status

Indicates data communication is taking place via a Fronius Solar Net or that a data communications error has occurred

Inverter number

Sets the number (= address) of the inverter in a system with several solar inverters

Unit -

Setting range 00 - 99 (00 = 100th inverter)

Factory setting 01

IMPORTANT! If a number of inverters are linked together in a data communications system, assign a unique address to each one.

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Protocol type

Specifies the communications protocol to be used to transfer the data:

Unit -

Setting range Solar Net / Interface

Factory setting Solar Net

Device Info For displaying the settings that will be of relevance to an energy supply company. The val-

ues shown will depend on the country setup or the device-specific settings of the inverter.

Display area General / MPP Tracker / Grid Monitoring / Voltage Limits / Fre-

quency Limits / P AC Reduction

General:

Setup Country setup

Version Version of country setup

Group Group for updating the inverter software

MPP Tracker:

DC Mode DC mode

FIX Voltage value in V for fixed voltage operation

User Voltage value in V for MPP User operation

Grid Monitoring:

GMTi Start-up time of inverter in s

GMTr Reconnection time in s following a grid fault

ULL Mean grid voltage over 10 minutes in V.

LL Trip Trip time for long-term voltage monitoring

Voltage Limits:

UIL max Upper inner grid voltage in V

UIL min Lower inner grid voltage in V

UOL max Upper outer grid voltage limit value in V

UOL min Lower outer grid voltage limit value in V

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Frequency Limits:

FIL max Upper inner grid frequency in Hz

FIL min Lower inner grid frequency in Hz

FOL max Upper outer grid frequency limit value in Hz

FOL min Lower outer grid frequency limit value in Hz

LVFRT:

Status Status of the LVFRT function (Low Voltage Fault Ride Through,

according to BDEW TR3 5.7)

DB min Dead Band Value min.

Lower voltage limit as % for the reactive power feed

DB max Dead Band Value max.

Upper voltage limit as % for the reactive power feed

k-Fac Gradient showing how much reactive current is fed in as a func-

tion of voltage

P AC Reduction:

Max. P AC Manual power reduction

GPIS Softstart function

GFDPRv Grid frequency-dependent power reduction in %/Hz

GFDPRr Return to nominal output in %/s (following a grid frequency-in-

duced power reduction)

Device Status For displaying the measured insulation resistance

Display area Messwertanzeige

PV Iso. (Value in MOhm)

Time Setting time and date

Unit HH:MM, DDMMYYYY

Setting range Time/date

Factory setting -

IMPORTANT! The correct time and date is a prerequisite for the correct display of day and year values and the day characteristic.

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Status LT The status display of the most recent inverter fault can be displayed.

IMPORTANT! Due to the low level of insolation early in the morning and in the evening,

the status codes 306 (Power low) and 307 (DC low) are displayed routinely at these times of day. These status messages do not indicate any kind of fault.

- Press the 'Enter' key to see the status of the power stage set and the most recent fault

- Use the 'Up' and 'Down' keys to scroll through the list

- Press the 'Back' key to close the status and fault list

Grid Status The five most recent grid faults can be displayed:

- Press the 'Enter' key to see the five most recent grid faults

- Use the 'Up' and 'Down' keys to scroll through the list

- Press the 'Back' key to close the grid fault display

Fan test To check that the fan is working correctly

Unit -

Setting range Start (Progress)

Factory setting -

The fan test is started by pressing the 'Enter' key. While the test is ongoing, its ' Progress' is shown on the display.

OK Fan test successful Fail Fan is defective; the associated status code is displayed in 'NOW' view mode.

Version Displays the version and serial numbers of the PC boards in the inverter (e.g. for service

purposes)

Unit -

Display area Display / Display Software / Interface / SmartMedia Card / Con-

trol / Control Software / Monitoring / Monitoring Software / Interface

Factory setting -

Page 78

Setting and displaying the menu items

Setting the menu items, general

Accessing the set-up menu

Use the 'Up' or 'Down' buttons to select the desired menu item

Press 'Enter'

The first digit of a value to be set flashes:

Use the 'Up' or 'Down' buttons to se-

lect a value for the first digit

Press 'Enter'

The second digit of the value flashes.

Repeat steps 4 and 5 until ...

the whole value to be set flashes.

Press 'Enter'

Repeat steps 4 - 6 as required for

units or other values that are to be set until the appropriate unit or the value flashes.

Press the 'Enter' key to save and ap-

ply the changes.

The available settings are displayed:

Use the 'Up' or 'Down' buttons to se-

lect the desired setting

Press the 'Enter' key to save and ap-

ply the setting.

To discard the setting, press the 'Esc' key.

To discard the changes, press the 'Esc' key.

The currently selected menu item is displayed.

Page 79

Exiting a menu item

To exit a menu item, press the 'Back' key

The menu level appears:

If no key is pressed for 2 minutes,

- the inverter switches from wherever it is within the Setup menu back to the 'NOW' display mode (exception: 'Standby' menu item),

- the display backlighting goes out,

- The amount of energy currently fed in is displayed.

Practical examples for setting and displaying menu items

Setting the display backlighting

The setting and displaying of menu items is illustrated using the following examples:

- Setting the display backlighting

- Setting the currency and feed-in tariff

- Setting the time and date

Select the 'Backlight' menu item

Press the 'Enter' key

The current setting for the display backlighting is shown.

Use the 'Up' and 'Down' keys to select

the desired setting for the display backlighting

Press the 'Enter' key to apply the set-

ting

The settings for the display backlighting are applied. The 'Backlight' menu item is displayed.

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Setting the currency and feed-in tariff

Select the 'Currency' menu item

Press the 'Enter' key to apply the cur-

rency

The currently selected currency is displayed, factory setting = 'EUR'; the first of the three characters starts flashing.

Use the 'Up' and 'Down' keys to select

a value for the first character

Press the 'Enter' key

The second character starts flashing.

Repeat steps 3 and 4 for the second

and third characters until...

the selected currency starts flashing.

Press the 'Enter' key

The currency is applied and the present feed-in tariff in currency/kWh displayed, factory setting = 0.43 EUR / kWh; the first digit starts flashing.

Use the 'Up' and 'Down' keys to select

a value for the first digit (e.g. 0)

Press the 'Enter' key

The second digit starts flashing.

Repeat steps 7 and 8 for the second

digit and for each of the three digits after the decimal point until ...

Page 81

the selected feed-in tariff starts flashing.

Setting the time and date

YIELD DATCOM

Press the 'Enter' key

The feed-in tariff is applied and the 'Currency' menu item is displayed.

Select the 'Time' menu item

Press the 'Enter' key

The time is displayed (HH:MM:SS, 24-hour format), the hours field starts flashing.

Use the 'Up' and 'Down' keys to select

a value for the hour

Press the 'Enter' key

The minutes field starts flashing.

Repeat steps 3 and 4 for the minutes

and seconds until...

the set time starts flashing.

Press the 'Enter' key

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The time is applied and the date now appears (DD.MM.YYYY), the day field starts flashing.

Use the 'Up' and 'Down' keys to select

a value for the day

Press the 'Enter' key

The month field starts flashing.

Repeat steps 7 and 8 for the month

and the last 2 digits of the year until ...

the set date starts flashing.

Press the 'Enter' key

YIELD DATCOM

The date is applied and the 'Time' menu item is displayed.

Page 83

Switching the key lock on and off

General The inverter has a key lock function.

When the key lock is active, the Setup menu is not accessible, i.e. the setup data cannot be changed accidentally (or maliciously). The code 12321 has to be entered in order to activate / deactivate the key lock.

Switching the key lock on and off

Acess Code

Press the 'Menu' key

'MENU' is displayed.

Press the unassigned 'Menu / Esc'

key 5 times

'Access Code' is displayed in the 'CODE' menu; the first digit starts flashing.

Enter the code 12321: use the 'Up'

and 'Down' keys to select a value for the first digit of the code.

Press the 'Enter' key

The second digit starts flashing.

Repeat steps 3 and 4 for the second,

third, fourth and fifth digit of the access code until ...

the selected code starts flashing.

Press the 'Enter' key

'Key Lock' is displayed in the 'LOCK' menu.

Use the 'Up' and 'Down' keys to turn

the key lock on or off:

ON = key lock is on (the Setup menu is not accessible)

OFF = key lock is off (the Setup menu is accessible)

Press the 'Enter' key

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Page 85

Troubleshooting and maintenance

Page 86

Page 87

Status diagnostics and troubleshooting

Displaying status codes

Total failure of the display

Class 1 status codes

The inverter performs a system self diagnosis that automatically detects many faults that may occur and shows them on the display. This means you are promptly made aware of malfunctions in the inverter and the photovoltaic system, or of any installation or operating faults.

If the system self diagnosis has detected a specific fault, the associated status code will be shown on the display.

IMPORTANT! Status codes may sometimes appear briefly as a result of the inverter's control response. If the inverter then continues working with no sign of any problem, this means that there was no fault.

If the display fails to come on some time after sunrise:

- Check the AC voltage ON the inverter connections: the AC voltage must be 230 V (+ 10 % / - 5 %)*.

* The mains voltage tolerance depends on the country setup

Class 1 status codes generally only arise momentarily and are caused by the public grid.

The initial response of the inverter in this case is to disconnect itself from the grid. The grid is subsequently checked for the stipulated monitoring period. If no further problem has been detected by the end of this period, then the inverter will resume feeding energy into the grid.

Depending on the country setup, the SoftStart-function GPIS is activated: after cutting out due to an AC fault, the output power of the inverter is continuously increased by 10% every minute in line with the VDE-AR-N 4105 guideline.

102

AC voltage too high

Behaviour Following careful testing and when the grid conditions are within

the permissible range again, the inverter will resume feeding energy into the grid.

Remedy Check grid connections

If this status code keeps recurring, contact your system engineer

103

AC voltage too low

Behaviour Following careful testing and when the grid conditions are within

the permissible range again, the inverter will resume feeding energy into the grid.

Remedy Check grid connections

If this status code keeps recurring, contact your system engineer

Page 88

105

AC frequency too high

Behaviour Following careful testing and when the grid conditions are within

the permissible range again, the inverter will resume feeding energy into the grid.

Remedy Check grid connections

If this status code keeps recurring, contact your system engineer

106

AC frequency too low

Behaviour Following careful testing and when the grid conditions are within

the permissible range again, the inverter will resume feeding energy into the grid.

Remedy Check grid connections

If this status code keeps recurring, contact your system engineer

107

No AC grid

Behaviour Following careful testing and when the grid conditions are within

the permissible range again, the inverter will resume feeding energy into the grid.

Remedy Check grid connections

If this status code keeps recurring, contact your system engineer

108

Stand alone operation detected

Behaviour Following careful testing and when the grid conditions are within

the permissible range again, the inverter will resume feeding energy into the grid.

Remedy If this status code keeps recurring, contact your system engi-

neer

Page 89

Class 3 status codes

Class 3 includes status codes that may occur while feeding energy into the grid, but generally do not cause the process to be interrupted for any length of time.

The inverter disconnects automatically from the grid, the grid is then monitored as specified and the inverter attempts to resume feeding energy into the grid.

301

Overcurrent (AC)

Behaviour Short-term interruption while feeding energy into the grid due to

overcurrent in the alternating current circuit The inverter resumes with its startup routine.

Remedy Fault is rectified automatically

If this status code keeps recurring, contact your system engineer

303

Power module overtemperature

Behaviour Short-term interruption while feeding energy into the grid due to

overtemperature The inverter resumes with its startup routine.

Remedy Purge cooling air openings and heat sink if necessary;

fault is rectified automatically If this status code keeps recurring, contact your system engineer

304

Internal temperature too high

Behaviour Short-term interruption while feeding energy into the grid due to

overtemperature The inverter resumes with its startup routine

Remedy Purge cooling air openings and heat sink if necessary;

fault is rectified automatically If this status code keeps recurring, contact your system engineer

305

If the grid relay is closed, no energy is transferred to the grid

Behaviour Permanent interruption while feeding energy into the grid

Remedy If this status code keeps recurring, contact your system engi-

neer

307 (DC low)

DC input voltage too low for feeding energy into the grid

Behaviour Short-term interruption while feeding energy into the grid

The inverter resumes with its startup routine.

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Remedy Fault is rectified automatically

If this status code keeps recurring, contact your system engineer

IMPORTANT! Due to the low level of insolation early in the morning and in the evening, the status code 307 (DC low) is routinely displayed at these times of day. This status code does not indicate any kind of fault.

309

DC input voltage too high

Behaviour Short-term interruption while feeding energy into the grid

The inverter resumes with its startup routine.

Remedy Fault is rectified automatically

If this status code keeps recurring, contact your system engineer

321

Overcurrent (AC)

Behaviour Short-term interruption while feeding energy into the grid due to

a grid fault or a power module fault The inverter resumes with its startup routine.

Class 4 status codes

Remedy Fault is rectified automatically

If this status code keeps recurring, contact your system engineer

322

Overtemperature on the air intake sensor

Behaviour Permanent interruption while feeding energy into the grid

Remedy Reduce the ambient temperature and ensure that a suitable hot

air extractor is installed if necessary If this status code keeps recurring, contact your system engineer

Some of the class 4 status codes necessitate intervention by a Fronius-trained service engineer.

401

No communication with power stage set possible

Behaviour The inverter will automatically attempt to connect again and, if

possible, will resume feeding energy into the grid

Remedy If the status code is displayed all the time: notify a Fronius-

trained service engineer

406

Power module temperature sensor defective

Behaviour The inverter is disconnected from the grid for safety reasons.

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Remedy If the status code is displayed all the time: notify a Fronius-

trained service engineer

407

Internal temperature sensor defective

Behaviour The inverter is disconnected from the grid for safety reasons.

Remedy If the status code is displayed all the time: notify a Fronius-

trained service engineer

412

Fixed voltage mode has been selected instead of MPP voltage mode, and the fixing voltage has been set at too low or too high a value.

Behaviour The fixed voltage is lower than the current MPP voltage.

Remedy Check module voltage and change the connection of the solar

modules if the input voltage is too high; If the status code appears all the time: notify a Fronius-trained service engineer

415

External Emergency Stop line is blocked

Behaviour The inverter is disconnected from the grid for safety reasons.

Remedy Fault is rectified automatically;

If this status code keeps recurring: notify a Fronius-trained service engineer

416

No communication possible between power stage set and control system

Behaviour The inverter is disconnected from the grid for safety reasons.

Remedy If the status code is displayed all the time: notify a Fronius-

trained service engineer

425

No communication possible with the power module

Behaviour The inverter is disconnected from the grid for safety reasons

and then attempts a restart.

Remedy If the status code is displayed all the time: notify a Fronius-

trained service engineer

426

Intermediate circuit charging takes too long

Behaviour Short-term interruption while feeding energy into the grid

The inverter resumes with its startup routine.

Remedy Fault is rectified automatically

If this status code keeps recurring, contact your system engineer

Page 92

427

Power stage set not ready for too long (timeout)

Behaviour Short-term interruption while feeding energy into the grid

The inverter resumes with its startup routine.

Remedy Fault is rectified automatically

If this status code keeps recurring, contact your system engineer

431

Bootloading process interrupted

Behaviour The inverter is in bootloading mode and is not feeding any en-

ergy into the grid

Remedy Repeat the update process

If the status code is displayed all the time: notify a Froniustrained service engineer

436

Receiving incorrect fault information from the power stage set

Behaviour Short-term interruption while feeding energy into the grid

The inverter resumes with its startup routine.

Remedy Fault is rectified automatically

If this status code keeps recurring, contact your system engineer

437

General error handling started in the power stage set

Behaviour Short-term interruption while feeding energy into the grid

The inverter resumes with its startup routine.

Remedy Fault is rectified automatically

If this status code keeps recurring, contact your system engineer

438

Receiving incorrect fault information from the power stage set

Behaviour Short-term interruption while feeding energy into the grid

The inverter resumes with its startup routine.

Remedy Fault is rectified automatically

If this status code keeps recurring, contact your system engineer

445

- Compatibility error (e.g. due to replacement of a PC board)

- Invalid power stage set configuration

Behaviour The inverter is not feeding any energy into the grid.

Page 93

Remedy Update the inverter firmware;

If the status code is displayed all the time: notify a Froniustrained service engineer

457

Mains relay sticking

Behaviour The inverter is not feeding any energy into the grid.

Remedy notify a Fronius-trained service engineer

459

Error when recording the measurement signal for the insulation test

Behaviour The inverter is not feeding any energy into the grid.

Remedy notify a Fronius-trained service engineer

460

Reference voltage source for the digital signal processor (DSP) is working out of tolerance

Behaviour The inverter is not feeding any energy into the grid.

Remedy If the status code is displayed all the time: notify a Fronius-

trained service engineer

461

Fault in the DSP data memory

Behaviour The inverter is not feeding any energy into the grid.

Remedy If the status code is displayed all the time: notify a Fronius-

trained service engineer

463

AC polarity reversed

Behaviour The inverter is not feeding any energy into the grid.

Remedy Update the inverter firmware

If the status code is displayed all the time: notify a Froniustrained service engineer

472

Fuse for solar module grounding is faulty

Behaviour The inverter is not feeding any energy into the grid.

Remedy Replace fuse for solar module grounding - notify a Fronius-

trained service engineer; if this status code keeps recurring, contact your system engineer

475

Solar module grounding, insulation fault (connection between solar module and ground)

Behaviour The inverter is disconnected from the grid for safety reasons.

Page 94

Remedy If the status code is displayed all the time: notify a Fronius-

trained service engineer

486

- External NO contact is open

- Optional measuring and monitoring relay has tripped

Behaviour The inverter is not feeding any energy into the grid.

Remedy Close external NO contact;

check measuring and monitoring relay If this status code keeps recurring, contact your system engineer

487

Air inlet temperature sensor is faulty

Behaviour The inverter is not feeding any energy into the grid.

Remedy Replace air inlet temperature sensor - notify a Fronius-trained

service engineer

488

AC measurement device is faulty

Behaviour The inverter is not feeding any energy into the grid.

Remedy notify a Fronius-trained service engineer

490, 491

Internal communication error

Behaviour The inverter is not feeding any energy into the grid.

Remedy notify a Fronius-trained service engineer

492

DC main switch is switched off

Behaviour The inverter is not feeding any energy into the grid.

Remedy Switch on DC main switch

493

DC relay is faulty

Behaviour The inverter is not feeding any energy into the grid.

Remedy notify a Fronius-trained service engineer

494

Grounding fault on the control board

Behaviour The inverter is not feeding any energy into the grid.

Remedy notify a Fronius-trained service engineer

Page 95

495

The 3 V supply voltage on the control board is faulty

Behaviour The inverter is not feeding any energy into the grid.

Remedy notify a Fronius-trained service engineer

496

The 5 V supply voltage on the control board is faulty

Behaviour The inverter is not feeding any energy into the grid.

Remedy notify a Fronius-trained service engineer

497

The 14 V or 22 V supply voltage for the PWM driver is faulty

Behaviour The inverter is not feeding any energy into the grid.

Remedy notify a Fronius-trained service engineer

498

The 24 V supply voltage for the power electronics is faulty

Class 5 status codes

Behaviour The inverter is not feeding any energy into the grid.

Remedy notify a Fronius-trained service engineer

499

The 24 V supply voltage on the control board is faulty

Behaviour The inverter is not feeding any energy into the grid.

Remedy notify a Fronius-trained service engineer

Class 5 status codes do not generally interfere with feeding energy into the grid, but can cause restrictions. A status code is displayed until it is acknowledged by pressing a key (the inverter, however, continues to operate normally in the background).

502

Insulation error on the solar modules

Description Warning message is shown on the display

Remedy If the status code is displayed all the time: notify a Fronius-

trained service engineer

509

No energy fed into the grid in the past 24 hours

Description Warning message is shown on the display

Page 96

Remedy Check that all the conditions for feeding energy into the grid

without any problems have been satisfied. If the status code is displayed all the time: notify a Froniustrained service engineer

516

No communication possible with the storage unit

Description Storage unit warning message

Remedy If the status indicator appears all the time: notify a Fronius-

trained service engineer

517

Power derating caused by too high a temperature

Description Warning message when power derating occurs

Remedy If the status indicator appears all the time: notify a Fronius-

trained service engineer

518

Internal DSP malfunction

Description Warning message is shown on the display

Remedy If the status indicator appears all the time: notify a Fronius-

trained service engineer

535

Error during fan self-test

Description Warning message is shown on the display

Remedy If the status indicator appears all the time: notify a Fronius-

trained service engineer

536

Main fan error

Description Warning message is shown on the display

Remedy If the status indicator appears all the time: notify a Fronius-

trained service engineer

551

Fuse for solar module grounding is faulty

Description Warning message is shown on the display

Remedy Replace fuse for solar module grounding - notify a Fronius-

trained service engineer; if this status code keeps recurring, contact your system engineer

555

Circulating fan error

Description Warning message is shown on the display

Page 97

Remedy If the status indicator appears all the time: notify a Fronius-

trained service engineer

558

Functional incompatibility (one or more PC boards in the inverter are not compatible with each other, e.g. after a PC board has been replaced)

Description Possible device errors or malfunctions on the inverter

Remedy Update the inverter firmware using the Fronius Solar.update

software; the latest inverter firmware is available from http://www.fronius.com. If the status indicator appears all the time: notify a Froniustrained service engineer

560

Power derating caused by overfrequency

Description The status code is displayed from a grid frequency of 50.2 Hz

and above. The inverter reduces the power along a 40%/Hz slope. The inverter switches off at a grid frequency of 51.5 Hz. The status indicator is displayed until the inverter returns to normal operation.

Remedy From a frequency of 50.2 Hz and above, the inverter tries to re-

connect to the grid. The fault is rectified automatically as soon as the inverter returns to normal operation. If the status indicator appears all the time: notify a Froniustrained service engineer

597

External overvoltage protection has tripped (connected to the "IN1" NO/alarm contact terminals)

Description Warning message is shown on the display

Remedy Replace overvoltage protection - notify a Fronius-trained ser-

vice engineer

598

External overvoltage protection has tripped (connected to the "IN2" NO/alarm contact terminals)

Description Warning message is shown on the display

Remedy Replace overvoltage protection - notify a Fronius-trained ser-

vice engineer

599

External overvoltage protection has tripped (connected to the "IN3" NO/alarm contact terminals)

Description Warning message is shown on the display

Remedy Replace overvoltage protection - notify a Fronius-trained ser-

vice engineer

Page 98

Class 7 status codes

Class 7 status codes relate to the control system, the configuration and inverter data recording, and may directly or indirectly affect the process of feeding energy into the grid.

701 - 716

Provides information about the internal processor program status

Description Is of no concern when the inverter is working properly and only

appears in the "Status PS" setup parameter. In the event of an actual error, this status code supports Fronius TechSupport during the error analysis.

721

EEPROM has been re-initialised

Description Warning message is shown on the display

Remedy If the status code is displayed all the time: notify a Fronius-

trained service engineer

722 - 730

Provides information about the internal processor program status

Description Is of no concern when the inverter is working properly and only

appears in the "Status PS" setup parameter. In the event of an actual error, this status code supports Fronius TechSupport during the error analysis.

751

Time lost

Description Warning message is shown on the display

Remedy Reset the time and date

If the status code is displayed all the time: notify a Froniustrained service engineer

752

Real Time Clock module faulty

Description Warning message is shown on the display

Remedy Reset the time and date

If the status code is displayed all the time: notify a Froniustrained service engineer

753

Time not set for a long period (> 1/2 year)

Description Warning message is shown on the display

Remedy Reset the time and date

If the status code is displayed all the time: notify a Froniustrained service engineer

754, 755

Provides information about the internal processor program status

Page 99

Description Is of no concern when the inverter is working properly and only

appears in the "Status PS" setup parameter. In the event of an actual error, this status code supports Fronius TechSupport during the error analysis.

757

Hardware error in the Real Time Clock module

Description Warning message is shown on the display; the inverter is not

feeding any energy into the grid

Remedy If the status code is displayed all the time: notify a Fronius-

trained service engineer

761 - 765

Provides information about the internal processor program status

Description Is of no concern when the inverter is working properly and only

appears in the "Status PS" setup parameter. In the event of an actual error, this status code supports Fronius TechSupport during the error analysis.

766

Emergency derating has been activated (max. 750 W)

Description Warning message is shown on the display

Remedy If the status code is displayed all the time: notify a Fronius-

trained service engineer

767

Provides information about the internal processor program status

Description Is of no concern when the inverter is working properly and only

appears in the "Status PS" setup parameter. In the event of an actual error, this status code supports Fronius TechSupport during the error analysis.

768

Different power derating in the hardware modules

Description Warning message is shown on the display

Remedy If the status code is displayed all the time: notify a Fronius-

trained service engineer

772

Storage unit not available

Description Warning message is shown on the display

Remedy If the status code is displayed all the time: notify a Fronius-

trained service engineer

773

Software update group 0 (invalid country setup)

Description Warning message is shown on the display

Page 100

Remedy If the status code is displayed all the time: notify a Fronius-

trained service engineer

775

PMC power stage set not available

Description Warning message is shown on the display

Remedy Press the 'Enter' key to acknowledge the error

If the status code is displayed all the time: notify a Froniustrained service engineer

776

Invalid device-type

Description Warning message is shown on the display

Remedy Press the 'Enter' key to acknowledge the error

If the status code is displayed all the time: notify a Froniustrained service engineer

781 - 794

Provides information about the internal processor program status

Class 10 - 12 status codes

Customer service

Description Is of no concern when the inverter is working properly and only

appears in the "Status PS" setup parameter. In the event of an actual error, this status code supports Fronius TechSupport during the error analysis.

799

No communication between the control board and the monitoring board

Behaviour The inverter is not feeding any energy into the grid.

Remedy notify a Fronius-trained service engineer

1000 - 1299- Provide information on the status of the internal processor program

Description Is of no concern when the inverter is working properly and only

appears in the "Status PS" setup parameter. In the event of an actual error, this status code assists Fronius Technical Support during the error analysis.

IMPORTANT! Contact your Fronius dealer or a Fronius-trained service technician if

- an error appears frequently or all the time

- an error appears that is not listed in the tables

Fronius Fronius Agilo Outdoor 75.0-3 / 100.0-3 Operating Instruction [EN]

Specifications and Main Features

Frequently Asked Questions

User Manual