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Installation manual
SolarMax TS-SV330TS-SV / 360TS-SV
SolarMax Produktions GmbH
Zur Schönhalde 10
D-89352 Ellzee
E-Mail: [email protected]
© SolarMax Produktions GmbH 2015
4
Contents1 About this installation manual 61.1 Field of applicability 61.2 Target group 61.3 Where to keep this manual 61.3 Symbols used in this manual 6
2 Safety 72.1 Safety instructions 72.2 Appropriate use 8
3 Description of the station components 93.1 SolarMax TS-SV inverter 93.1.1 Block diagram of the TS-SV inverter 103.1.2 External operating elements and dimensions 113.1.3 Scope of delivery 113.2 TS-SV master control unit (MCU) 123.2.1 Exterior view and dimensions of the MCU 123.3 Configuration variants of the station 133.3.1 Multi MPPT operation mode 143.3.2 Single MPPT operation mode 153.4 Additional station components 163.4.1 DC fuse unit 163.4.2 Autonomous power supply transformer 163.4.3 Medium-voltage transformer 173.4.4 Medium-voltage switchgear 18
4 Installation 194.1 Transport & storage of the inverter 194.1.1 Means of transport 194.1.2 Storage conditions 204.2 Site selection and operating conditions of the inverter 204.2.1 Specifications and instructions for site selection 204.2.2 Operating conditions at the site 214.2.3 Cooling system of the inverter 224.3 Recommendations for station construction 224.3.1 Heating 234.3.2 Excavating the construction site 234.4 Lightning protection 244.5 Montage 244.5.1 Inverters 244.5.2 MCU 24
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5 Electrical connection 255.1 Guidelines for electrical installation 255.2 Earthing of the station components 255.3 Connecting the inverter 265.3.1 Interior view of the inverter 265.3.2 Connecting the inverters to the PV plant 275.3.3 Connecting the inverters to the medium voltage transformer 305.3.4 Connecting the inverters to the modular bus 325.3.5 Assigning addresses to the power units 335.3.6 Connecting the shutdown contact 1 (optional) 345.4 Connecting the MCU 365.4.1 Interior view of the MCU 365.4.2 Connecting the DC feed line to the MCU 375.4.3 Connecting the AC feed line to the MCU 375.4.4 Connecting the MCU to the modular bus 385.4.5 Connecting the protective earth (PE) line to the MCU 385.4.6 Interface and contacts of the MCU 385.5 Configuring the MCU 415.6 Connecting the other station components 425.7 Application examples for single-MPPT operation 435.7.1 DC fuse unit with several DC bus bars 445.7.2 DC Fuse unit with common DC bus bar 46
6 Commissioning 486.1 Inspections prior to startup 486.1.1 Identification and characteristics 486.1.2 Station 486.1.3 Inverters 496.1.4 Operational configuration and MCU 496.1.5 DC wiring in general 496.1.6 DC wiring for multi MPPT operation 496.1.7 DC wiring for single MPPT operation 506.1.8 AC wiring 506.1.9 Data communication 506.1.10 Earthing 506.2 Commissioning (Initial Setup) 51
7 Technical data 537.1 Efficiency curve 557.2 Temperature-dependent output reduction 577.3 Individual country settings 587.3.1 SM330TS-SV 587.3.2 SM360TS-SV 60
8 Warranty 63
6
1 About this installation manual
1.1 Field of applicability
This installation manual describes how to install and commission the inverters SM330TS-SV, SM360TS-SV (TS-SV inverters) and the control unit TS-SV Master Control Unit (MCU).
1.2 Target group
This installation manual is intended for the station outfitter (responsible qualified elec-trician) who is responsible for building the station and designing the project-specific components.
1.3 Where to keep this manual
The system operator must ensure that this installation manual is available to those responsible for the power plant at all times. If this original manual is lost, an up-to-date version can be downloaded from our website at all times (www.solarmax.com).
1.3 Symbols used in this manual
From time to time you will see the following symbols when reading this installation manual:
DANGERThis symbol indicates that ignoring this instruction can lead directly to serious injury or death.CAUTIONThis symbol indicates that ignoring this instruction can lead to damage to your inverter or your PV power plant.NOTEThis symbol indicates information which is especially important for operating the inverter.
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2 Safety
2.1 Safety instructions
DANGER
■■ In daylight the PV generator supplies the inverter with a dangerously high DC voltage.
■■ Only qualified electricians who have already completely read and understood this manual in advance may install and open SolarMax inverters and the MCU.
■■ The inverter has to be installed in an enclosed electrical plant room.■■ The qualified electrician is responsible for adhering to the valid local application
installation and safety instructions.■■ Ignoring the installation and safety instructions shall cancel any and all warranty
and liability claims.■■ Touching live parts is life-threatening.■■ The inverters and the MCU must remain closed at all times during operation.■■ The DC and AC feed lines must be disconnected according to the instructions and
secured against being reconnected accidentally before you open the inverter or the MCU.
■■ After disconnecting the inverter wait at least 5 minutes before opening the device to permit internal capacitors to discharge.
NOTE
■■ This document cannot take the place of support from the distributor. For assis-tance please get in touch with your personal contact.
■■ Check that you have the current version of the document by visiting our website.
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2.2 Appropriate use
The SolarMax TS series inverters are designed exclusively to convert the direct current generated by PV modules into alternating current which conforms to the parameters of the public grid. Any other use is contrary to the purpose for which the inverters were designed.
The inverter may only be connected to a suitable medium-voltage transformer. It is not permitted to connect the unit directly to a medium-voltage switch circuit or to the power grid.
SolarMax Produktions GmbH accepts no liability for damages resulting from using inverters for purposes other than this. Any modifications to the inverter performed by the system operator or the electrician without a review and approval by SolarMax Produktions GmbH are prohibited.
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3 Description of the station components
This chapter describes the station components.
3.1 SolarMax TS-SV inverter
The main component of a station is the SolarMax TS-SV central inverter. It converts the PV generator’s direct current into alternating current which conforms to public grid parameters. The output of a station depends on the number of installed TS-SV inverters. One to four TS-SV inverters together with an MCU make up an inverter system that is connected to a medium-voltage transformer.
The TS-SV inverter consists of three independent power units. Each power unit has its own MPP tracker, DC-end overvoltage conductors, power switches on the DC and AC end (Q1 to Q6), a contactor at the AC end (K1 to K3) and EMV filters. All power switches are accessible from outside when the inverter casing is closed.
The control units of the power units have two digital signal processors (DSP) which assume all the monitoring, controlling and regulating tasks. All the safety-relevant values are continuously monitored and compared by both processors. The result is greater oper-ating safety and reliability. The DSP’s high performance enables precise and rapid identi-fication of the maximum power points (MPP) of the PV generator and, combined with the low-loss power unit, delivers maximum yields. The completely digital regulation ensures outstanding quality of the current fed into the grid which means extremely negligible grid reactions.
The inverters of the TS-SV series are capable of delivering reactive power if necessary to actively support the mains during short blackouts, to reduce output in response to rising mains frequency and to receive and implement remote control commands (power output reduction, etc.).
The inverter comes from the factory configured for multi-MPPT operation. All the DC inputs of the installed inverters must be connected in parallel and fitted with fuses for the single MPPT operating mode. A short description of these operating modes can be found in section 3.3 “Configuration variants of the station”.
The inverter is not fitted with potential separation. This is provided by the medium-voltage transformer.
10
3.1.1 Block diagram of the TS-SV inverter
U
PU1
K1
Sola
rMax
TS-
SV
U
PU2
K2
U
PU3
K3
ModuarBus (MCU)
23
23
23
DC In
put 1
DC p
ower
sw
itch
Q4AC
pow
er s
witc
h Q1
AC o
utpu
t 2
AC o
utpu
t 3
AC o
utpu
t 1
DC p
ower
sw
itch
Q5AC
pow
er s
witc
h Q2
DC p
ower
sw
itch
Q6AC
pow
er s
witc
h Q3
DC In
put 2
DC In
put 3
EMC
�lte
r
EMC
�lte
r
EMC
�lte
r
EMC
�lte
r
EMC
�lte
r
EMC
�lte
r
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3.1.2 External operating elements and dimensions
1970
1090
690
80
1200
8064
0
800
80
80 493 54 493
4 x ø
20
4 xM16 threaded cylinder (Fastening nuts for lift assembly)
DC power switch
AC power switch
Type plate
Opening for the modular bus cable
3.1.3 Scope of delivery
The scope of delivery may vary depending on the project specifications. But as a rule, along with the inverter or the MCU, the following parts are supplied:
■■ Inverters: – 4 x short perforated grid front/back – 2 x long perforated grid side – Hardware (screws, spring washers, etc.) – Phase separation elements – 1 Network cable RJ45 Cat. 6 S/FTP (2 m) – 4 eye bolts M16
■■ MCU: – 1 Network cable RJ45 Cat. 6 S/FTP (5 m) – 1 Network cable RJ45 Cat. 6 S/FTP (10 m) – Fastening elements – Operating manual
12
3.2 TS-SV master control unit (MCU)
The TS-SV master control unit (MCU) is the control and operating unit for as many as four TS-SV inverters. The interfaces and contacts of the MCU enable innumerable com-munications and monitoring variants, see 5.4.6 “Interfaces and contacts of the MCU”.
The MCU is connected to the TS-SV inverter via a modular bus interface. The MCU is powered both from the AC end (from the autonomous power supply transformer) as well as from the DC end. This enables the MCU to operate around the clock. The MCU has a switch that you can use to configure the single or multi MPPT operating mode see 5.5 “Configuring the MCU”.
The MCU has a mounting rail that enables the installation of the MaxWeb xp web-based data logger and the potential equalization set (PAS).
3.2.1 Exterior view and dimensions of the MCU
600 150
520
550
470
Graphics display
status LED
Main switch
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3.3 Configuration variants of the station
Using the TS-SV inverter as basic module, stations with the following output powers can be built:
Number of SM330TS-SV Max. apparent output [kVA]
1 340 kVA
2 680 kVA
3 1 020 kVA
4 1 360 kVA
Number of SM360TS-SV Max. apparent output [kVA]
1 370
2 740
3 1 110
4 1 480
The TS-SV inverter enables the realisation of stations in either a multi or single MPPT operating mode.
NOTE
■■ The station must be designed for either the multi MPPT or for the single MPPT operating mode. It is not possible to mix operating modes.
■■ The combination of SM330TS-SV and SM360TS-SV inverters in the same station is neither permitted nor technically possible.
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3.3.1 Multi MPPT operation mode
In the multi MPPT operating mode each power unit operates its own MPP tracker, allowing the connection of as many as three mutually independent PV generators to each TS-SV inverter.
Station with three TS-SV inverters in the multi MPPT operating mode
TS-SV
3
3
PU1
PU2
PU3
PU1
PU2
PU3
TS-SV
TS-SV
PU1
PU2
PU3 ModularBus
ModularBus
3
MCU
DC input 1
DC input 2
DC input 3
DC input 4
DC input 5
DC input 6
DC input 7
DC input 8
DC input 9
MV transformer
AC output
For this variant, the MCU assumes the master control of the TS-SV inverter, and also acts as a joint user interface and enables the integration of the station into a MaxComm communications network.
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3.3.2 Single MPPT operation mode
In single MPPT operating mode all the DC inputs of the inverters are wired parallel inside the station. The shared MPP tracker is monitored for all the power units by the MCU.
Station with three TS-SV inverters in the single MPPT operating mode
PU1
PU2
PU3
PU1
PU2
PU3
PU1
PU2
PU3
3
3
3
MCU
TS-SV
TS-SV
TS-SV
ModularBus
ModularBus
DC input1
DC input 2
DC input 3
DC input 4
DC input 5
DC input 6
DC input7
DC input 8
DC input 9
AC output
DC fuse units
MV transformer
DC fuse units
DC fuse units
For this variant, the MCU acts as a master MPP tracker control unit for all the TS-SV inverters, and also acts as a joint user interface and enables the integration of the station into a MaxComm communications network.
The DC inputs are connected in parallel outside the inverters, usually as part of the DC fuse box.
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3.4 Additional station components
The following station components are not supplied by SolarMax Produktions GmbH:
■■ DC fuse box■■ Autonomous power supply transformer (transformer for the station‘s own power
supply)■■ Medium voltage transformer and 400 V low-voltage installation■■ Medium voltage switchgear■■ AC fuses between each inverter and the medium-voltage transformer
The design of these components is in the hands of the station outfitter. The details con-tained in the following sections are only standard values and typical characteristics.
3.4.1 DC fuse unit
The DC fuse unit is only needed if the intention is to operate the station in single MPPT operating mode. The station outfitter is responsible for constructing the DC fuse unit. When you dimension the DC fuse unit keep in mind the connection conditions for the single MPPT operating mode, see 5.3.2 “Connect inverter to the PV plant”.
3.4.2 Autonomous power supply transformer
The autonomous power supply transformer powers the MCU and other, project dependent consumers (lighting, MaxWeb xp, fans, etc.) inside a station. The use of an autonomous power supply transformer is necessary if no local 230 V / 400 V mains are available. The selection and dimensioning of the transformer is in the hands of the station outfitter.
Typical characteristics
The actual size of the autonomous power supply transformer (if necessary) depends on the number and type of the additional consumers inside the station.
Technical data
Type 3 phases, 50 Hz
Power output ≥ 5 kVA
Number of 3-phase windings 2
Voltage 1 SM330TS-SV: 280 V (D)SM360TS-SV: 320 V (D)
Voltage 2 400 V (yn)
Vector group Dyn0
Protective class IP22
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Technical data
Max. ambient temperature 40 °C
3.4.3 Medium-voltage transformer
The medium-voltage transformer is the link between the local 280 V network within a sta-tion and the medium-voltage network. The inverter may only be connected to the power grid via a medium-voltage transformer. The medium-voltage transformer provides the potential separation between the PV power plant and the medium-voltage switch system or the power grid. The inverter does not have its own potential separation. The medium-voltage transformer is not included in the scope of supply.
Determining the size
The dimensioning of the medium-voltage transformer depends on the number of TS-SV inverters used. Dimension the medium-voltage transformer in such a way that its no-load losses remain as low as possible. The following reference values are applicable to a maximum ambient temperature of 40 °C.
Number of SM330TS-SV inverters Size of the medium-voltage transformer [kVA]
1 400
2 630
3 1 000
4 1 250
Number of SM360TS-SV inverters Size of the medium-voltage transformer [kVA]
1 400
2 800
3 1 000
4 1 600
Requirements
The requirements are listed in the following table, using a 1 000 kVA medium-voltage transformer as example:
1 000 kVA medium-voltage transformer
Type 3 phases / 50 Hz (on rollers)
Power output 1 000 kVA
Number of 3-phase windings 2 (1 MV, 1 LV)
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1 000 kVA medium-voltage transformer
Primary voltage (MV) 20 kV (depending on project and site)
Insulation level 24 kV
Primary (MV) tapping ±2.5 % and ±5 %
Secondary voltage (LV) SM330TS-SV: 0.28 kVSM360TS-SV: 0.32 kV
Standard IEC60076
Vector group Dd (no start point, phase is irrelevant)
Short circuit voltage UK 4 %…6 %
No-load losses < 1 300 W (oil) / < 2 000 W (dry) CC
Load losses (@75 °C) < 11 000 W CC
Environment Internal application (no air conditioning required)
Max. ambient temperature 40 °C
Max. installation altitude < 2 000 meters above sea level
Relative humidity 5 %…95 %
Insulation Basic insulation designed for pulse operation of an inverter
Test voltages 50 kV (medium voltage to low voltage) / 8 kV (low voltage to protective conductor PE)
In addition, the medium-voltage transformer must have a test record of the final test that con-tains details about the insulation measurements, no-load and full-load losses.
Requirements for oil-based medium-voltage transformers
In addition to the details in the “1 000 kVA medium-voltage transformers” table, oil-based medium-voltage transformers must have the following specification:
■■ Design Art IP00 NV / IP54 medium-voltage transformer and medium-voltage con-nector with hermetically closed tank
■■ Accessories: DGPT2 (full transformer protection)
3.4.4 Medium-voltage switchgear
The correct installation of the medium-voltage switchgear is in the hands of the station outfitter. The local regulations and guidelines must be followed.
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4 Installation4.1 Transport & storage of the inverter
DANGER
■■ The inverter is a heavy device which, if not handled properly, can tip over during transport and cause serious personal injuries.
■■ The inverter must be transported upright.
4.1.1 Means of transport
Forklift trucks
The inverter has openings in its base to allow it to be transported by a forklift truck. Secure the devices against falling.
Crane
At the upper corner struts the inverters have four M16 threaded cylinders (weld nuts). You can screw M16 eye bolts into these cylinders. These allow the inverter to be lifted by a crane or forklift truck.
DANGER
■■ If you use a forklift or some other lifting equipment take extreme caution. Make sure the lifting equipment has adequate lifting capacity.
■■ Secure the inverter against falling while it is being moved by a forklift truck.■■ Whenever this is done always make sure that the inverter’s weight is correctly
distributed on the lifting equipment (ensure that centres of gravity are properly distributed).
■■ Ropes or strips must have an angle of > 60° to the inverter top.
■■ Necessary minimum lifting capacity of the transport vehicle or lifting equipment: 950 kg (weight of the inverter).
20
4.1.2 Storage conditions
Store the inverter in a dry, enclosed space.
CAUTION
Possible damage to the device! Never store the inverter outdoors. Not even for a short time.
4.2 Site selection and operating conditions of the inverter4.2.1 Specifications and instructions for site selection
Choosing a suitable location for the inverter is decisive for its operating safety as well as its expected service life and efficiency. An ideal location is indoors or in a container with the following characteristics:
■■ The site must be dry to prevent any condensation from collecting in the inverter: no puddles, no damp masonry walls, no openings where snow or rain can enter.
■■ The ambient air of the inverter must be free from dust, salt, and ammonium vapours. If required (e.g. for installations near the sea or in desert areas), the ambient air of the inverter must be filtered (e.g. with an air conditioning unit or a filter).
■■ Do not install the inverter in rooms or work areas which contain or are made of com-bustible materials. Follow the local fire safety regulations.
DANGER!
Fatal electric shock hazard! – The inverter must be installed in an enclosed electrical plant room so that unauthorized persons have no access.
CAUTION
Fire hazard! - Suitable for mounting on concrete or other non-combustible surface only!
■■ Because the inverter is a source of noise, do not install it near residential spaces.■■ Make sure that the floor of the installation site is level and its bearing capacity is
adequate. ■■ The inverter must be installed on the entire contact face of the 6 bases.
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■■ To ensure that the inverter is accessible for possible repair work the front side must be at least 1 m away from the nearest object (wall, other inverters, etc.). Do not install the inverter on a raised surface, platforms or consoles.
■■ Where the inverter and the medium-voltage transformer are installed in separate rooms, a warning note must be attached to both units: „Before carrying out any work to the AC connection between the inverter and the medium-voltage transformer, the electricity connection to the supply lines to the PV generator and the medium-voltage network must be switched off“.
4.2.2 Operating conditions at the site
■■ The ambient conditions are specified in the technical data, see section 7.■■ The installation location must meet the requirements contained in the standard for
electromagnetic immunity for industrial environments (EN 61000-6-2) and for emis-sions in industrial environments (EN 61000-6-4).
NOTE
■■ Please remember that the inverter and existing accessories give off heat during operation which can contribute to a serious heating up of the ambient air if the plant rooms are small or poorly ventilated.
■■ Our basic rule is always to recommend that the ambient temperature be kept under 30 °C.
■■ The ventilation at the site must provide an air change rate of 5000 m3 per hour and inverter. The air must flow through the inverter from bottom to top.
■■ Conditions in the plant room which could lead to even a short period of excessive ambient air temperature (TAmbient > 50 °C) make the installation of an additional ventilation system an absolute necessity.
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4.2.3 Cooling system of the inverter
The inverter’s heat sinks are actively cooled by internal fans. The cool, fresh air enters the inverter from below, is drawn in by the fans and is blown upwards through the ventilation screens out of the inverter.
For safety reasons the heat sink temperature is limited to 85 °C. When ambient tem-perature is over 45 °C the heat sink temperature can reach 80 °C. If this happens, the maximum feed output is temporarily reduced and a corresponding status message appears on the inverter’s display screen. But if the temperature still runs as high as 85 °C the inverter is shut down to prevent a thermal overload.
NOTE
Optimal cooling is decisive for maximum inverter output yield. Install inverters only at a site corresponding to the description in 4.2.2 “Site selection and operating conditions”.
4.3 Recommendations for station construction
The construction and setup of the inverters in a station must meet the requirements of the IEC 62271 202 industrial standard.
The TS-SV inverters are generally built into a concrete station. The conception of the station depends on the country-specific standards and regulations for the construction of rooms containing electrical facilities and is the responsibility of the station outfitter.
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Example of a station with three TS-SV inverters:
D
d
d
d
1
2
7
6
5
1
13 4
Legend:D Clearance as set by country-specific regulationsd 1 metre1 SolarMax TS-SV inverter2 MCU 5 AC distribution3 DC fuse box 6 Medium voltage transformer4 Own power supply transformer 7 Medium voltage switchgear
4.3.1 Heating
The inverters are tested to operate at temperatures to -20 °C. Remember to check the minimum operating temperatures of the other components and, if necessary, to install a heating unit.
4.3.2 Excavating the construction site
The construction site must be excavated following the instructions of the station outfitter. Stations fitted with a basement ventilation system must be effectively protected against the intrusion of rain, snow and water through the lateral cooling shafts. There must be drainage channels and pipes in place and the subsurface soil must be permeable.
24
4.4 Lightning protection
The requirements for appropriate lightning protection for a PV power plant depend on many different factors (plant size, how the cables are run, the modules used, the sur-roundings, etc.).
A project-specific protection concept must be developed by a qualified person.
4.5 Montage4.5.1 Inverters
The inverters can be fastened to the floor with M12 screws. Use the hole pattern shown in 3.1.2 “External operating elements and dimensions”. In addition to anchorage to the ground the inverters can be anchored to the wall with a bracket above to the M16 threaded cylinders.
4.5.2 MCU
The MCU is usually mounted on the wall in the station. The hole pattern is shown in 3.2.1 “Exterior view and dimensions”.
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5 Electrical connection5.1 Guidelines for electrical installation
DANGER
■■ Only qualified electricians may install and start-up the TS-SV inverter and the MCU.
■■ The local regulations and guidelines for the installation of electrical devices must be followed.
■■ All the feed lines to the inverter and the MCU must be appropriate for the expected voltages, currents and ambient conditions (temperature, UV load, etc.).
■■ Make sure that all lines are laid tension-free.
5.2 Earthing of the station components
As a principle, all metal parts which are not protected against being touched must be earthed.
DANGER
A correct earthing is vital for the operation and safety of the devices (for example, by an earthing strap buried in the ground).
The station components must be earthed as follows:
■■ Each inverter with two 95 mm2 wires connected to M10 threaded bolts. The position of the MS threaded bolts: see 5.3.1 “Interior view of the inverter”.
■■ The MCU with one 10 mm2 wire (also important for perfect communication between the MCU and inverters). The position of the terminals: see 5.4.1 “Interior view of the MCU”. The MCU must be grounded independently of the inverters.
■■ Each of the DC fuse boxes with one 95 mm2 wire per box.■■ The star point of the 400 V coil of the autonomous power supply transformer.■■ The AC-side overvoltage protection of the inverter is earthed.
DANGER
Never ground the possibly existing low-voltage star point at the medium-voltage transformer!
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5.3 Connecting the inverter5.3.1 Interior view of the inverter
Open the inverter by loosening the four or three captive M5 screws of the left and right front cover.
DANGER
Make sure that all the DC and AC feed lines to the inverter are dead before you start the installation work.
16
8
1 2 3
15
14
13
9
10
11
12
7
4
5
6
15
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Legend:1 Power unit PU1 9 DC power switch Q42 Power unit PU2 10 DC power switch Q53 Power unit PU3 11 DC power switch Q64 AC power switch Q1 12 DC connections5 AC power switch Q2 13 Fuse holder (DC connection for MCU)6 AC power switch Q3 14 Shutdown contact 17 AC connections 15 Fans8 2 x M10 threaded bolts for earthing 16 Test contacts
5.3.2 Connecting the inverters to the PV plant
General connection conditions
■■ Per power unit as many as three DC feed lines (strings) can be connect in parallel.■■ Maximum DC input current per power inverter: 720 A■■ Maximum DC input voltage per inverter: 900 V■■ Maximum DC input current per power unit: 240 A■■ If the feed lines are long we recommend you use larger line cross sections to keep
down transmission losses. ■■ Maximum admissible over-dimensioning of the PV generator output power: 50 %.
NOTE
The DC inputs of the inverter are overvoltage protective Type 3.
Connection conditions for the multi MPPT operating mode
■■ It is not permitted to install a ground connection to the PV generator.■■ Starting from three DC feed lines for each power unit, the minimum cross section
increases because in case of a short circuit the two intact feed lines pass on all the return current to the defective line (the cross section increase for three DC feed lines can be dropped if all the DC feed lines are fitted with fuses):
Number of feed lines per power unit Minimum cable cross section
1 95 mm2
2 50 mm2
3 70 mm2
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Connection conditions for the single MPPT operating mode
■■ Minimum conductor cross section: 95 mm2
■■ All the DC inputs of the inverters in use must be connected in parallel.■■ The DC bus bars for connecting the inverters in parallel must be dimensioned for the
maximum current:
Number of inverters Maximum current in the DC bus bars [A]
2 720
3 960
4 1 440
■■ All DC feed lines must be individually fitted with fuses, both at the plus as well as the minus pole. Use 160 A NH fuses which have been certified for at least 1 000 VDC (the 160 A correspond to the max. DC total current of a MaxConnect combiner box).
■■ Installation of a ground connection to one pole of the PV generator is permissible (plus or minus pole).
DANGER
Fatal electric shock hazard! – When a pole of the PV generator is grounded (or func-tionally grounded), that pole must be considered as live and must be insulated.
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■■ Principle wiring diagram for single MPPT operating mode:
PU1
PU2
PU3
TS-SV
PU1
PU2
PU3
TS-SV
MCU
160 A /1000VDCNH fuses
DC input 1DC input 2
DC input n
DC input 1DC input 2
DC input n
DC bus bars
AC output
AC output
Procedure
DANGER
Make sure that all the DC and AC feed lines to the inverter are dead before you start the installation work.
1. Run the DC feed lines from below into the inverter and to the M8 threaded bolt connec-tions below the DC power switches.
2. Connect the DC feed lines of the strings correctly; (make sure the polarity is right). The correct order of the fastening elements is: Cable lug, spring lock washer, finally the M8 nut.
Tightening torque for the M8 nuts: minimum 20 Nm, maximum 25 Nm.
3. Implement the cable strain relief within the false floor of the station (in the inverter no cable strain relief is designed). The distance between DC connection within the in-verter and the cable strain relief should be less than 500 mm.
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DC connections
PU 1 PU 3PU 2
5.3.3 Connecting the inverter to the medium voltage transformer
Connecting conditions
■■ 3 x 95 mm2 per Phase (2 x 185 mm² per phase are also admissible).■■ The inverter is not fitted with potential separation. This is provided by the medium-
voltage transformer.■■ The maximum cable length between the inverter and the medium-voltage trans-
former must not exceed 30 meters.■■ The AC connection (280V / 320V) of the inverter must meet the requirements of the
overvoltage category II. The AC-side overvoltage protection must be correspondingly dimensioned.
■■ The AC connection of the inverter must be protected by an AC circuit breaker or an NH fuse switch disconnector (see chapter 5.6).
■■ If you use external residual current devices (RCDs), use the type A RCDs with a nominal fault current of at least 10 A per inverter. For PV plants with large stray cur-rent capacities, the RCDs to be used should have a nominal fault current capacity of at least 30 A per inverter.
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NOTE
■■ The inverter is not fitted with overvoltage protection on the AC side. ■■ The inverter does not have any devices (such as RCDs) for the protection against
dangerous touch currents or electric shock.■■ The inverter is fitted with a configurable DC insulation monitor (Vsym monitor, see
TS-SV operating manual).
Procedure
DANGER
Make sure that all the DC and AC feed lines to the inverter are dead before you start the installation work.
1. Run the AC feed lines from below into the inverter and to the M8 threaded bolt connec-tions below the AC power switches.
2. Connect the AC feed lines correctly.
– Remember that the rotating field of the mains phases must be clockwise.
– The correct order of the fastening elements is: Cable lug, spring lock washer, finally the M8 nut.
– Tightening torque for the M8 nuts: minimum 20 Nm, maximum 25 Nm.
3. Position the included phase separation elements between the cable lugs to ensure the isolation clearance.
4. Implement the cable strain relief within the false floor of the station (in the inverter no cable strain relief is designed). The distance between DC connection within the in-verter and the cable strain relief should be smaller than 500 mm.
32
AC connections
L1 L2 L3 L1 L2 L3 L1 L2 L3
5.3.4 Connecting the inverters to the modular bus
Each power unit must be connected to a ModularBus. The power units in the inverter are already connected to each other ex factory. You only must implement the ModularBus connections amongst the inverters.
Cable requirements
Cat. 6 S/FTP cable, 2/10 metres (included in delivery)
Procedure
Please use the supplied cables only. Connect the inverters by connecting the cable to the ModularBus sockets X631 or X632 of the respective power unit. Always terminate the ModularBus with a terminating plug.
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ModularBus connections
TS-SV MCU
PU 1
PU 2
PU 3
PU n (max 12)
zur TS-SV MCU
ModularBus-Adressenotieren
Staubschutz
Abschlussstecker
Kon�gurationstecker
5.3.5 Assigning addresses to the power units
An unambiguous address must be assigned to each power unit with the help of the con-figuration plug.
Procedure
1. Disconnect the configuration plug (the figure in section 5.3.4. shows the position of the configuration plug).
2. Configure the address with the configuration plug. The addresses are as follows:
Inverter-No. Adress Rotary switch position
1
1 1
2 2
3 3
34
Inverter-No. Adress Rotary switch position
2
4 4
5 5
6 6
3
7 7
8 8
9 9
4
10 A
11 B
12 C
3. Record the address set in front on the power unit.
4. Reconnect the configuration plugs.
5. Record the inverter number outside on the type plate.
Configuration plug
5.3.6 Connecting the shutdown contact 1 (optional)
Position of the shutdown contact 1 (SD1-SD4) in the inverter: see 5.3.1 “Interior view”.
The shutdown contacts 1 (SD1-SD4) enable remote shutdown of as many as eight inverters using an external break contact (e.g. an emergency off switch). If the shutdown function 1 is activated the current supply circuit of the AC contactor K1 is disconnected directly and the inverter is locked. This results in the immediate disconnection from the grid which is also effective when the control unit fails. The inverters remain locked until the external break contact is reclosed. In addition, the status message “Shutdown 1” is displayed.
The shutdown 1 is inactive if there is a short circuit between either the contact pair SD1 and SD2 (SD12) or SD3 and SD4 (SD34), e.g., with a plaited bridge. The shutdown 1 is only active if both contact pairs SD12 and SD34 are open. When shipped from the factory the contact pair SD12 is short-circuited with a plaited bridge.
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Cable requirements
Use the cable with the following line specifications for wiring the contacts:■■ Minimum cross section: 1.5 mm2
■■ Maximum cable length: 240 m (total length of break contact to the last inverter)
If you want to lock several inverters (as many as 8) with a single break contact, wire the shutdown contacts 1 as shown in the following diagram:
…
……
SD1
SD2
SD3
SD4
SD1
SD2
SD3
SD4
SD1
SD2
SD3
SD4
TS-SV #8TS-SV #1 TS-SV #2
Break contact
36
5.4 Connecting the MCU
This section describes how to connect the MCU inside the station correctly.
DANGER
Make sure that all the DC and AC feed lines are dead before you start the installation work.
5.4.1 Interior view of the MCU15
VDC
24 V
DCPAS MaxWeb xp
11 1
- +
Sola
rpa
rkX
821
Ethe
rne
tX
601
mod
ula
rTS
X80
2
Stat
us R
elai
sX
411
Exte
rne
r Ala
rmX
501
WR-
Frei
gab
eX
511M
axC
omm
X62
1
MCU Mod eS231
Num of LTsS241
Ans
chlu
ss P
AS
X22
01
MCU10 0
1
PEPE NL
DC+
DC
1
2 3 4 5 6 7 8
Legend:1 MCU2 Potential equalization set (optional)3 MaxWeb xp (optional)4 15 VDC power supply for MaxWeb xp (optional)5 24 VDC power supply for the MCU6 Terminal for protective earth (PE)7 Terminals for the AC power supply (L1, N, PE)8 Terminals for the DC power supply (DC+; DC-)
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5.4.2 Connecting the DC feed line to the MCU
The connection to the DC voltage of the PV generator ensures uninterrupted operation of the MCU in the case of a failure of the AC mains. In addition, the connection permits measuring the DC voltage by the MCU.
Cable requirements
2 x minimum 2.5 mm2 (900 VDC)
Procedure
1. Connect the cable to the terminals “DC+” and “DC−” within the MCU. Position of the terminals, see 5.4.1 “Interior view of the MCU”.
2. Connect the cable to the fuse holders “DC+” and “DC−” within the nearest inverter. Make sure the polarity is right. Position of the fuse holders: see 5.3.1 “Interior view of the inverter”.
DC+
DC
5.4.3 Connecting the AC feed line to the MCU
The autonomous power supply transformer or an available 230 V mains supplies the AC power to the MCU.
Cable requirements
■■ Supply voltage: 230 VAC
■■ Maximum power consumption: 60 W■■ Three-core cable; L1, N and PE (230 V); 3 x minimum 1 mm2
Procedure
Connect the cable to the terminals L1, N, and PE within the MCU. Position of the terminals: see 5.4.1 “Interior view of the MCU”.
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5.4.4 Connecting the MCU to the modular bus
Cable requirements
Cat. 6 S/FTP cable, 5 metres (included in delivery)
Procedure
1. Connect the cable to the modular bus “X802” socket of the MCU.
2. Connect the cable to a free modular bus socket (X631 or X632) at the nearest power unit, see also 5.3.4 “Connecting inverters to the modular bus”.
5.4.5 Connecting the protective earth (PE) line to the MCU
Cable requirements
■■ Minimum cable cross section: 6 mm2, maximum cable cross section: 16 mm2
■■ The MCU must be grounded independently of the inverters.
Procedure
Connect the protective earth to the 16 mm2 terminal. The position of the terminal: see 5.4.1 “Interior view of the MCU”.
5.4.6 Interface and contacts of the MCU
Integrated RS485 and Ethernet interfaces enable many communications and monitoring options based on our MaxComm communications platform. The system communicates either directly via a PC with MaxTalk (from version 2.0) or via the Internet enabled MaxWeb xp data logger.
In addition, contacts for switching the inverters on and off, for remote monitoring of the MCU, for a MaxConnect alarm input as well as contacts for connecting the potential equalization set (PAS) are integrated.
NOTE
Additional information on the use of various interfaces and functions of the MCU can be found in the operating manual of the TS-SV inverter.
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Interfaces and contacts of the MCU
11 1
- +
Solar
park
X821
Ethe
rnet
X601
mod
ular
TSX8
02
Stat
us R
elais
X411
Exte
rner
Alar
mX5
01
WR-
Frei
gabe
X511
Max
Com
mX6
21
MCU ModeS231
Num of LTsS241
Ansc
hlus
s PAS
X220
1
MCU100
1
5.4.6.1 Cable requirements for the contacts
Unless otherwise stated, use cable with the following specifications for wiring the contacts:
■■ Minimum cross section: 0.75 mm2
■■ Minimum cross section: 4 mm2
■■ Maximum cable length: 50 m
5.4.6.2 Status signalling contact – X411
The status signalling contact X411 enables the MCU and the inverter to be remotely moni-tored. The MCU status can be recorded with the potential-free relay contacts NO and COM. How the status signalling contact works can be selected in the “Settings” menu (see the operating manual of the TS-SV inverter).
The list of events that trigger the status signalling contact can be found in the operating manual of the TS-SV inverter.
NC
1
NO C
X411
40
■■ Specifications of the status signalling contact – Contacts potential-free (make contact), not fused – Max. switch voltage: 250 VAC / 100 VDC
– Max. switch current: 5 Aeff @ 250 VAC (cosφ = 1) or 30 VDC
– Continuous current: 2 Aeff
5.4.6.3 Shutdown contact 2 – X511
The shutdown contact 2 (X511) allows the inverter to be remotely shut down via an external break contact. The function is similar to the one of shutdown contact 1, but the separation from the grid is not made directly via the supply voltage of the AC contactor K1. It is controlled by software via the inverter’s control unit. The inverters remain locked until the external break contact is reclosed. In addition, the status message “Shutdown 2” is displayed. The shutdown 2 is inactive, if EN1 and EN2 (EN12) are short-circuited by a bridge (condition at the time of delivery). The shutdown 2 is active if the contact pair EN12 is open.
5.4.6.4 Alarm contact – X501
The alarm contact (X501) is used to display the status of the generator connection box MaxConnect plus in the graphics display. For this purpose use a two-wire cable to connect the contacts of the potential-free fault alarm output of MaxConnect plus to the STM and GND contacts on the inverter’s terminal block. As soon as the STM and GND contacts are short-circuited, the inverter display shows the status message “Warning MaxConnect”.
5.4.6.5 Connection PAS - X2201
Interface for the connection of the potential equalization set (PAS). Use the cable supplied with the potential equalization set.
NOTE
The potential equalization set (PES) may only be used for stations configured for single MPPT operation. Contact the SolarMax Service Center, if you want to connect the potential equalization set.
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5.4.6.6 RS485 interfaces – X621 / X 821 and Ethernet – X601
The MCU provides two RS485 interfaces and an Ethernet interface for data communica-tions. You can integrate the MCU with these RJ45 sockets into a MaxComm communi-cations network to use the extensive monitoring and remote control options offered by SolarMax Produktions GmbH. You can learn more about the advantages of the MaxComm communications platform in the operating manual of the TS-SV inverter.
Use the network cable (referred to as “patch cable”) to wire the Cat 5 interfaces.
5.5 Configuring the MCU
The switches for the necessary settings are located on the motherboard of the MCU and should be switched with a No. 2 screwdriver. The position of the switch: see 5.4.6 “Inter-faces and contacts of the MCU”.
Configuring the MCU for single or multi MPPT operating mode
Turn the switch “S231” (MCU Mode) to the required position.
TS-SV inverter Configuration Switch positionSM330TS-SV Single MPPT operating mode 2
Multi MPPT operating mode 3SM360TS-SV Single MPPT operating mode 4
Multi MPPT operating mode 5
Define the number of connected power units
Rotate the switch “S241” (Num of LTs) to the correct position:
Switch position 0 1 2 3 4 5 6 7 8 9 A B C D E F
Number of power units
N/A3
N/A6
N/A9
N/A12
N/ANumber of inverters 1 2 3 4
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5.6 Connecting the other station components
The correct electrical installation of the following components is in the hands of the sta-tion outfitter. SolarMax Produktions GmbH instructions in this regard are limited:
AC circuit breaker
To protect the inverter and to permit its complete AC-side disconnection, an AC power switch must be connected to the AC connection of the inverter.
Specification AC circuit breaker:
■■ Maximum current: 800 A■■ Maximum voltage: 280 V (SM330TS-SV) / 320 V (SM360TS-SV)■■ Thermal and magnetic overcurrent release
Alternatively, an NH switch disconnector fuse with 800A NH fuses may also be used.
Medium voltage transformer
Standard values for dimensioning and typical characteristics can be found in 3.4.3 “Medium-voltage transformer”.
Autonomous power supply transformer
The star point on the secondary side (400 V) must be earthed. On the primary side (280 V / 320 V), no star point is necessary. The autonomous power supply transformer must be fused on the primary and secondary sides.
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5.7 Application examples for single-MPPT operation
This section shows two examples of applications using three SM330TS-SV inverters and a TS-SV-MCU in each case. Both stations are designed for single-MPPT operation.
In the example in subsection 5.7.1 three DC bus bars are used. One DC bus bar for every central inverter. The DC bus bars are connected to each other with connection cables. The 315 amp fuses protect the connection cables. If the currents are balanced, no current flows in the connection cables. If the currents are not balanced, the current in the con-nection cables will not exceed 315 amp. The 315 amp fuses allow individual inverters to be disconnected from the DC input.
In the example in subsection 5.7.2 all DC inputs of the central inverters are connected in parallel to a common DC bus bar. In that case, the connection cables are not necessary. The 315 amp fuses can be dropped. Arrange the connections over the entire length of the DC bus bar, so that the current at a certain point cannot exceed 960 amp.
DANGER
■■ Only qualified electricians who have already completely read and understood this installation manual in advance may install and open SolarMax inverters.
■■ The qualified electrician is responsible for adhering to the valid local application installation and safety instructions.
44
5.7.1 DC fuse unit with several DC bus bars
PU1
PU3
PU2
PU1
PU3
PU2
PU1
PU3
PU2
95 mm2 95 mm2
95 mm2
95 mm2
95 mm2
95 mm2
95 mm2
95 mm2
95 mm2
95 mm2
95 mm2
95 mm295 mm2
95 mm295 mm2
95 mm295 mm2
95 mm295 mm2
SM330TS-SV
L1
L2
L3
X631
Adress #7(X541)
DC+DC-
L1
L2
L3
Terminal plug onModularTS X632
X631
Adress #9(X541)
L1
L2L3
X631
Adress #8(X541)
SM330TS-SV
L1
L2
L3
X631
Adress #4(X541)
DC+DC-
L1
L2
L3
X631
Adress #6(X541)
L1
L2
L3
X631
Adress #5(X541)
SM330TS-SV
L1
L2
L3
ModularTSX632
ModularTSX632
ModularTSX632
ModularTSX632
ModularTSX632
ModularTSX632
ModularTSX632
ModularTSX632
X631250 A250 A
Adress #1(X541)
DC+
DC-
L1
L2
L3
X631250 A250 A
Adress #3(X541)
L1
L2
L3
X631250 A
250 A
Adress #2(X541)
ModularBus
Cat. 6 S/FTP 2 m or 10 m (included in delivery)
Cat. 6 S/FTP 2 m or 10 m (included in delivery)
RS485PE
MaxConnect 16 plus
160 A
RS485 MaxConnect
5 x 160 A
5 x 160 A
5 x 160 A
RS485PE
MaxConnect 16 plus
160 A
RS485PE
MaxConnect 16 plus
160 A
RS485PE
MaxConnect 16 plus
160 A
RS485PE
MaxConnect 16 plus
160 A
RS485PE
MaxConnect 16 plus
160 A
RS485PE
MaxConnect 16 plus
160 A
Overvoltage protection
Type 2
2 x 6 A
160 A1000 VDCNH
315 A1000 VDCNH
315 A1000 VDC
NH
DC bus bars
Connectioncables
720 A
185 mm2 185 mm2
DC fuse unit
45
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46
5.7.2 DC Fuse unit with common DC bus bar
PU1
PU3
PU2
PU1
PU3
PU2
PU1
PU3
PU2
95 mm2 95 mm2
95 mm2
95 mm2
95 mm2
95 mm2
95 mm2
95 mm2
95 mm2
95 mm2
95 mm2
95 mm295 mm2
95 mm295 mm2
95 mm295 mm2
95 mm295 mm2
SM330TS-SV
L1
L2
L3
X631
Adress #7(X541)
DC+DC-
L1
L2
L3
Terminal plug onModularTS X632
X631
Adress #9(X541)
L1
L2L3
X631
Adress #8(X541)
SM330TS-SV
L1
L2
L3
X631
Adress #4(X541)
DC+DC-
L1
L2
L3
X631
Adress #6(X541)
L1
L2
L3
X631
Adress #5(X541)
SM330TS-SV
L1
L2
L3
ModularTSX632
ModularTSX632
ModularTSX632
ModularTSX632
ModularTSX632
ModularTSX632
ModularTSX632
ModularTSX632
X631250 A250 A
Adress #1(X541)
DC+
DC-
L1
L2
L3
X631250 A250 A
Adress #3(X541)
L1
L2
L3
X631250 A
250 A
Adress #2(X541)
ModularBus
Cat. 6 S/FTP 2 m or 10 m(included in delivery)
Cat. 6 S/FTP 2 m or 10 m(included in delivery)
RS485PE
MaxConnect 16 plus
160 A
RS485 MaxConnect
5 x 160 A
5 x 160 A
5 x 160 A
RS485PE
MaxConnect 16 plus
160 A
RS485PE
MaxConnect 16 plus
160 A
RS485PE
MaxConnect 16 plus
160 A
RS485PE
MaxConnect 16 plus
160 A
RS485PE
MaxConnect 16 plus
160 A
RS485PE
MaxConnect 16 plus
160 A
Overvoltage protection
Type 2
2 x 6 A
160 A1000 VDCNH
DC bus bars
960 A
DC fuse unit
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48
6 Commissioning6.1 Inspections prior to startup
Go through the following check lists before you startup the inverters and the MCU for the first time. Keep the filled-out check lists for service requests.
6.1.1 Identification and characteristics
Plant nameStreet, postal code, townPlant outputDate of first startupTS-SV Master Control Unit: S/N:TS-SV inverter #1 S/N:TS-SV inverter #2 S/N:TS-SV inverter #3 S/N:TS-SV inverter #4 S/N:Type and quantity of generator connection boxesMaxWeb xp S/N:Quantity Power units
6.1.2 Station
Nr. OK NOK Check1. ❑ ❑ The station (site) meets the IP standard and the specs contained in the installation manual.2. ❑ ❑ The minimum ventilation of 5 000 m3/h per inverter is provided.3. ❑ ❑ The ventilation inlets and outlets are open and free of blockage.4. ❑ ❑ The ventilation inlets are at least 15 cm above the floor.5. ❑ ❑ The regulations regarding the replacement of ventilation filters (if necessary) are available
at the site.6. ❑ ❑ The thermostat is set to 30 °C.7. ❑ ❑ The covers on the ventilation inlets (if necessary, e.g. screens against rodents) are in
place. 8. ❑ ❑ Water or snow cannot penetrate into the station.9. ❑ ❑ Condensation (formation of droplets) cannot penetrate into the inverter.10. ❑ ❑ The inverters in the station are easily accessible for maintenance work.11. ❑ ❑ The minimum distances from the inverter to other inverters and objects in the station is at
least 1 meter.12. ❑ ❑ The minimum distance between the inverter and the ceiling is 50 cm.13. ❑ ❑ The maximum floor load of the site has not been exceeded.
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6.1.3 Inverters
Nr. OK NOK Check14. ❑ ❑ The inverter is clean and there is no visible mechanical damage.15. ❑ ❑ There are no tools or other foreign objects in the inverter.Nr. OK NOK Check16. ❑ ❑ The inverter is firmly screwed down (for transportable stations).17. ❑ ❑ The ventilation inlets and outlets of the inverter are open and free.18. ❑ ❑ The rubber bushings for the communications cable are in place.19. ❑ ❑ All the covers in the inverter are in place.20. ❑ ❑ All the circuit breakers of the inverter are switched off.21. ❑ ❑ The outer covers of the inverter are in place.
6.1.4 Operational configuration and MCU
Nr. OK NOK Check22. ❑ ❑ The wiring of the inverter does not allow a mixed multi MPPT and single MPPT operation.23. ❑ ❑ The MCU is configured for the correct operating mode: Multi MPPT or single MPPT operation.24. ❑ ❑ The MCU is configured for the right quantity of all power units in the station.25. ❑ ❑ The main switch of the MCU is off.26. ❑ ❑ The MCU is closed and locked.
6.1.5 DC wiring in general
Nr. OK NOK Check27. ❑ ❑ The connection of the strings to MaxConnect or another generator connection box (if pres-
ent) complies with local installation regulations.28. ❑ ❑ The maximum input voltage of the inverter of 900 V is not exceeded.29. ❑ ❑ The maximum input current of 240 A per power unit is not exceeded.30. ❑ ❑ The cross section of the line for the DC connection in the inverter is at least 2 x 95 mm2
and no more than 2 x 150 mm2 per power unit.31. ❑ ❑ The DC feed lines in the inverter have been connected correctly polarized. The tightening
torque of the nuts is in conformance with the specs in the installation manual.32. ❑ ❑ The DC voltage supply to the MCU is connected.
6.1.6 DC wiring for multi MPPT operation
Nr. OK NOK Check33. ❑ ❑ The inputs of the power units are not wired in parallel (there are no bridges between the
inputs of the power units).34. ❑ ❑ If the DC feed lines have no fuses: The minimum line cross section conforms with the num-
ber of DC feed lines as described in the installation manual.
50
6.1.7 DC wiring for single MPPT operation
Nr. OK NOK Check35. ❑ ❑ The inputs of the power units are outside of the inverter wired in parallel with the DC
busbars.36. ❑ ❑ The DC feed lines between the DC busbars and the inputs of the inverter have been fused.37. ❑ ❑ The DC busbars have been dimensioned and fused for the maximum possible current
specified in the installation manual (see 5.7 Application examples).38. ❑ ❑ The DC feed lines between the PV module or MaxConnect and the DC busbars are fitted
with fuses. These have been fitted both on the plus pole and the minus pole. 39. ❑ ❑ The DC feed lines between the PV modules or between MaxConnect and the DC busbars
are dimensioned for the maximum possible current.
6.1.8 AC wiring
Nr. OK NOK Check40. ❑ ❑ The measurement of the AC voltage prior to commissioning the station revealed the follow-
ing values: SM330TS-SV: 270 V … 285 V / SM360TS-SV: 310 V … 330 V.41. ❑ ❑ The AC overvoltage protection conforms with the requirements of overvoltage category 2.42. ❑ ❑ The line cross section for the AC connection in the inverter is no less than
3 x 95 mm2 per phase.43. ❑ ❑ The AC feed lines in the inverter have been correctly connected (mains phases are
clockwise). The tightening torque of the 9 nuts is in conformance with the specs in the installation manual.
44. ❑ ❑ The delivered phase separation elements have been fitted between the lugs inside the inverter.
45. ❑ ❑ Each inverter can be disconnected separately by an AC circuit breaker or an 800A NH fuse switch disconnector on the AC side.
46. ❑ ❑ The autonomous power supply transformer is fused on the primary and secondary sides.
6.1.9 Data communication
Nr. OK NOK Check47. ❑ ❑ The modular bus connection between the MCU and the closest inverter is realised with the
Cat. 6 S/FTP communications cable included in the delivery (5m cable).48. ❑ ❑ The modular bus connections between the inverters are realised with the Cat. 6 S/FTP
communications cables included in the delivery (2 m and 10 m cable).49. ❑ ❑ The terminal plug for the modular bus is plugged into the final power unit.50. ❑ ❑ Each of the power units has a unique modular bus address. The addresses have been
assigned in conformance with the instructions in the installation manual.
6.1.10 Earthing
Nr. OK NOK Check51. ❑ ❑ All the earth connections have been check with the ohmmeter.52. ❑ ❑ The inverter is earthed with two 95 mm2 earthing cables.53. ❑ ❑ The MCU is earthed to the station with a 10 mm2 earthing cable.54. ❑ ❑ The star point of the 400 V-coil of the transformer for the station's own power supply is
earthed.55. ❑ ❑ The AC-side overvoltage protection of the inverter is earthed.56. ❑ ❑ the DC fuse box is earthed with a 10 mm2 earthing cable to the station.
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Nr. OK NOK Check57. ❑ ❑ The star point of the low-voltage (if present) of the medium-voltage transformer is
NOT earthed.
CAUTION
Before you switch on the inverter, fit all the available protective covers, cover plates and perforated grids. The AC and DC power switches, and the main switch, can be operated from outside the closed device.
6.2 Commissioning (Initial Setup)
If the inverter is being commissioned the initial setup will start automatically. This pro-cedure must only be carried out once as part of the commissioning process. Information about operating the display is contained in the operating manual of the TS-SV inverter.
1. Switching on the inverter Switch on the MCU and the inverters as described in the operating manual of the
TS-SV inverter.
2. Selecting the display language In this step select the language in which the following information and texts in the
display will appear.
3. Selecting the individual country settings The individual country settings permit making such settings as the required mains
voltage and mains frequency range used in the country of installation. The selection of the country of installation is independent of the selected display language.
4. Date and time Set the local time and current date. The date set is stored as the commissioning date
and can be accessed later in the “Information” menu.
5. Confirming the entries Now confirm the completion of the initial setup with the button .
52
CAUTION
The individual country settings (step 3) must be entered with extreme care. Once the initial setup is completed the selections are permanently set and can no longer be modified. A wrong selection can lead to problems when operating the inverter and result in the license to operate being revoked by the local grid operator. An overview of the available country settings are contained in the operation manual of the TS-SV inverter.
NOTE
You can change all the settings in the initial setup (with the exception of the individual country settings) at any time in the “Settings” menu.
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7 Technical dataSM330TS-SV SM360TS-SV
Input values MPP voltage range 450 V…800 V 510 V…800 V
Maximum DC voltage 900 V 900 V
Maximum DC current 720 A 720 A
Number of MPP-Trackers 1 (Single MPPT operation) or 3 (Multi MPPT operation)
Isc PV 1 410 A (Single MPPT operation) / 3 x 470 A Multi MPPT operation
Reverse current 0 A (diode for protection against polarity reversal)
Connection type threaded bolts M8
Overvoltage category 2
Output values Rated output power 330 kW1) 360 kW2)
Max. apparent output power 340 kVA 370 kVA
Nominal mains voltage 3 x 280 V 3 x 320 V
Maximum AC current 700 A 666 A
Mains nominal frequency / range
50 Hz / 45 Hz…55 Hz (60 Hz / 55 Hz...65 Hz upon request)
Power factor cosφ adjustable from 0.8 overexcited to 0.8 underexcited
Harmonic distortionat rated output < 3 %
Connection type threaded bolts M8
Grid connection three-phase (without neutral conductor)
Maximum short-circuit current
1 506 A peak (1 ms) / 702 A RMS (≤ 1003) ms)
1 506 A peak (1 ms) / 666 A RMS (≤ 1003) ms)
Overcurrent protection 750 A (250 A per power unit)
Overvoltage category 2
Efficiency Max. efficiency 98 % 98 %
Europ. Efficiency 97.2 %4) 97.4 %4)
Power input Own consumption night < 7 W
Ambient conditions
Protection type compliant with EN 60529 IP20
Ambient temperature range −20 °C…+50 °C
Ambient temperature range for rated power output −20 °C...+45 °C
Relative humidity 0…98% (no condensation)
Degree of soiling PD2
Maximum altitudeabove sea level 2 000 m (without derating))
Noise emissions < 65 dBA (↔1.5 m)
Required fresh air 5 000 m3 / h
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SM330TS-SV SM360TS-SV
Configuration Casing Steel structure, powder-coated
Display (in MCU) Graphic LC display with backlight and status LED
Data logger (in MCU) Data logger for energy yield, peak output and operating duration for the last 31 days, 12 months and 10 years
DC power switch Thermomagnetic triggering, type N, 36 kA
AC power switch Thermomagnetic triggering, type N, 36 kA
Isolation monitoring yes (configurable function)
Protection class (EN61140) I
Galvanic isolation No galvanic isolation: direct connection to medium-voltage transformer
Standards &guidelines
CE-compliant yes5)
EMC EN 61000-6-2 / EN 61000-6-4
Standard / guideline compliance G59/2 / BDEW MV Guideline / PPC Guide / RD 661
Device safety IEC/EN 62109-1
Interfaces Data communication (in MCU) 2 x RS485 (RJ45) / 1 x Ethernet (RJ45)
Status signalling contact (in MCU)
Potential-free terminal contact pair (configurable function)
Alarm input (in MCU) Terminal contact pair for connection to MaxConnect plus
Inverter shutdown 1 Two terminal contact pairs (can be chain-linked via several MCU’s)
Inverter shutdown 2 (in MCU) Terminal contact pair
Test contacts For the functional test of grid monitoring
Weight & dimensions
Weight 950 kg
Dimensions (W x H x D) 1 200 x 1 970 x 800 mm
Warranty Standard warranty 2 years (free extension to 5 years after registration)
Warranty extensions to 10, 15, 20, or 25 years
1) at cosφ = 1, Uac = 280 V2) at cosφ = 1, Uac = 320 V3) up to 1 000 ms with activated FRT function (Fault-Ride-Through)4) in Single MPPT operation with active partial load optimisation (see operating manual parameter
configuration with MaxTalk 2 Pro)5) the complete conformity declaration can be found on our website at www.solarmax.com
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TS-SV Master Control Unit (MCU)
AC voltage supply Maximum input voltage 230 VAC
Maximum input current 1.05 A
Start-up current 100 A
Start-up current duration 30 ms
Frequency 50…60 Hz
DC voltage supply Maximum input voltage 900 VDC
Weight & dimensions Weight 10 kg
Dimensions (W x H x D) 600 x 520 x 150 mm
7.1 Efficiency curve
Efficiency curve Single MPPT - SM330TS-SV100 %
98 %
96 %
94 %
92 %
90 %
88 %
86 %
84 %
82 %
80 %0 % 10 % 20 % 30 % 40 % 50 % 60 % 70 % 80 % 90 % 100 %
η 450 VDC
η 550 VDC
Effic
ienc
y η [
%]
Standardised output Pac/Pac max [%]
56
Efficiency curve Multi MPPT - SM330TS-SV
100 %
98 %
96 %
94 %
92 %
90 %
88 %
86 %
84 %
82 %
80 %0 % 10 % 20 % 30 % 40 % 50 % 60 % 70 % 80 % 90 % 100 %
η 450 VDC
η 550 VDC
Effic
ienc
y η [
%]
Standardised output Pac/Pac max [%]
Efficiency curve Single MPPT - SM360TS-SV100 %
98 %
96 %
94 %
92 %
90 %
88 %
86 %
84 %
82 %
80 %0 % 10 % 20 % 30 % 40 % 50 % 60 % 70 % 80 % 90 % 100 %
η 510 VDC
η 600 VDC
Effic
ienc
y η [
%]
Standardised output Pac/Pac max [%]
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7.2 Temperature-dependent output reduction
The inverter can feed 100 % of its rated output for an unlimited time up to an ambient temperature of 45 °C. In the temperature range from 45 °C to 50 °C yield losses have to be expected, at 50 °C the inverter can still feed in 90 % of its rated output for an unlimited time. For this reason ambient temperatures exceeding 45 °C must be strictly avoided.
Stan
dard
ised
out
put [
PAC/P
nom
]
Ambient temperature [°C]
-20
1.2
1.0
0.8
0.6
0.4
0.2
0
-10 0 10 20 30 40 50
Umgebungstemperatur [°C]
Norm
iert
e Le
istu
ng [P
AC /
P NOM]
58
7.3 Individual country settings
NOTE
MaxTalk 2 Pro can be used by authorized and trained personnel to individually adjust the operating parameters. MaxTalk 2 Pro: professional version of MaxTalk for the con-figuration of inverters. The required "SolarMax TS-SV series parameter configuration using MaxTalk 2 Pro" operating manual can be downloaded from our website at www.solarmax.com ("Downloads" area).
7.3.1 SM330TS-SV
Parameter Unit Germany Spain Italy France Great Britain
Vac min 1 V 224 238 84 224 246.4
t Vac min 1 ms 2000 200 2000 200 2500
Vac max 1 V 322 308 364 336 305.2
t Vac max 1 ms 100 200 200 200 1000
Vac min 2 V 126 - - - 226.8
t Vac min 2 ms 1500 0 0 0 500
Vac max 2 V - - - - 313.6
t Vac max 2 ms 0 0 0 0 500
Vac 10min max V - - - - -
f min 1 Hz 47.5 48 45.5 47 47.5
t f min 1 ms 100 200 200 200 20000
f max 1 Hz 51.5 51 54.5 52 51.5
t f max 1 ms 100 200 200 200 90000
f min 2 Hz - - - - 47
t f min 2 ms 0 0 0 0 500
f max 2 Hz - - - - 52
t f max 2 ms 0 0 0 0 500
Restart delay s 0 0 300 0 0
Mains check On/Off On On Off On On
- Vac MC max V 364 308 308 336 305.2
- Vac MC min V 266 238 238 224 246.4
- f MC max Hz 50.05 51 50.1 52 51.5
- f MC min Hz 47.5 48 49.9 47 47
- t MC monitoring s 0 180 30 0 180
Island Detection On/Off Off On Off Off On
OV Detection On/Off On On On On On
Soft Start W/s - - - - -
Pac Progression %/min - - 20 - -
P(f)-Mode (1/2/3/Off) 1 Off 3 Off Off
- f start Hz 50.2 50.2 50.3 50.2 50.2
- f stop Hz 50.05 - 50.1 - -
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Parameter Unit Germany Spain Italy France Great Britain
- MC f max Hz - - 50.1 - -
- MC f min Hz - - 49.9 - -
- MC time s 0 0 300 0 0
- Reduction %/Hz 40 40 83 40 40
- Re-increase %/min - 10 5 10 10
Q mode Off Off Off Off Off
FRT On/Off On On On Off Off
- K factor 2.0 1.0 0.0 0.0 0.0
S max SM330TS-SV kVA 342 342 342 342 342
Pac max SM330TS-SV kW 342 342 342 342 342
Iac max SM330TS-SV A 702 702 702 702 702
Parameter Unit China USA Other Other 60 Hz
Vac min 1 V 238 246.4 238.0 246.4
t Vac min 1 ms 2000 2000 1500 2000
Vac max 1 V 308 308 322.0 308
t Vac max 1 ms 2000 1000 200 1000
Vac min 2 V 140 140 - 140
t Vac min 2 ms 100 160 0 160
Vac max 2 V - 336 - 336
t Vac max 2 ms 0 160 0 160
Vac 10min max V - - - -
f min 1 Hz 49.5 59.3 47 59.3
t f min 1 ms 600500 2000 500 2000
f max 1 Hz 50.2 60.5 52 60.5
t f max 1 ms 120500 160 500 160
f min 2 Hz 48 57 - 57
t f min 2 ms 200 160 0 160
f max 2 Hz 50.5 - - -
t f max 2 ms 200 0 0 0
Restart delay s 0 0 0 0
Mains check On/Off On On On On
- Vac MC max V 308 296.8 322 296.8
- Vac MC min V 238 257.6 238 257.6
- f MC max Hz 50.2 60.5 51 60.5
- f MC min Hz 49.5 59.3 47 59.3
- t MC monitoring s 60 300 30 300
Island Detection On/Off On On Off On
OV Detection On/Off On On
Soft Start W/s 1140 - - -
Pac Progression %/min - - - -
P(f)-Mode (1/2/3/Off) Off Off Off Off
- f start Hz 50.2 60.2 50.2 60.2
- f stop Hz - 60.05 - 60.05
- MC f max Hz - - - -
- MC f min Hz - - - -
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Parameter Unit China USA Other Other 60 Hz
- MC time s 0 0 0 0
- Reduction %/Hz 40 40 40 40
- Re-increase %/min 10 - 10 -
Q mode Off Off Off Off
FRT On/Off On Off Off Off
- K factor 0.0 0.0 0.0 0.0
S max SM330TS-SV kVA 342 342 342 342
Pac max SM330TS-SV kW 342 342 342 342
Iac max SM330TS-SV A 702 702 702 702
7.3.2 SM360TS-SV
Parameter Unit Germany Spain Italy France Great Britain
Vac min 1 V 256 272 96 256 281.6
t Vac min 1 ms 2000 200 2000 200 2500
Vac max 1 V 368 352 416 384 348.8
t Vac max 1 ms 100 200 200 200 1000
Vac min 2 V 144 - - - 259.2
t Vac min 2 ms 1500 0 0 0 500
Vac max 2 V - - - - 358.4
t Vac max 2 ms 0 0 0 0 500
Vac 10min max V - - - - -
f min 1 Hz 47.5 48 45.5 47 47.5
t f min 1 ms 100 200 200 200 20000
f max 1 Hz 51.5 51 54.5 52 51.5
t f max 1 ms 100 200 200 200 90000
f min 2 Hz - - - - 47
t f min 2 ms 0 0 0 0 500
f max 2 Hz - - - - 52
t f max 2 ms 0 0 0 0 500
Restart delay s 0 0 300 0 0
Mains check On/Off On On Off On On
- Vac MC max V 416 352 352 384 348.8
- Vac MC min V 304 272 272 256 281.6
- f MC max Hz 50.05 51 50.1 52 51.5
- f MC min Hz 47.5 48 49.9 47 47
- t MC monitoring s 0 180 30 0 180
Island Detection On/Off Off On Off Off On
OV Detection On/Off On On On On On
Soft Start W/s - - - - -
Pac Progression %/min - - 20 - -
P(f)-Mode (1/2/3/Off) 1 Off 3 Off Off
- f start Hz 50.2 50.2 50.3 50.2 50.2
- f stop Hz 50.05 - 50.1 - -
- MC f max Hz - - 50.1 - -
- MC f min Hz - - 49.9 - -
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Parameter Unit Germany Spain Italy France Great Britain
- MC time s 0 0 300 0 0
- Reduction %/Hz 40 40 83 40 40
- Re-increase %/min - 10 5 10 10
Q mode Off Off Off Off Off
FRT On/Off On On On Off Off
- K factor 2.0 1.0 0.0 0.0 0.0
S max SM360TS-SV kVA 369 369 369 369 369
Pac max SM360TS-SV kW 369 369 369 369 369
Iac max SM360TS-SV A 666 666 666 666 666
Parameter Unit China USA Other Other 60 Hz
Vac min 1 V 272 281.6 272 281.6
t Vac min 1 ms 2000 2000 1500 2000
Vac max 1 V 352 352 368 352
t Vac max 1 ms 2000 1000 200 1000
Vac min 2 V 160 160 - 160
t Vac min 2 ms 100 160 0 160
Vac max 2 V - 384 - 384
t Vac max 2 ms 0 160 0 160
Vac 10min max V - - - -
f min 1 Hz 49.5 59.3 47 59.3
t f min 1 ms 600500 2000 500 2000
f max 1 Hz 50.2 60.5 52 60.5
t f max 1 ms 120500 160 500 160
f min 2 Hz 48 57 - 57
t f min 2 ms 200 160 0 160
f max 2 Hz 50.5 - - -
t f max 2 ms 200 0 0 0
Restart delay s 0 0 0 0
Mains check On/Off On On On On
- Vac MC max V 352 339.2 368 339.2
- Vac MC min V 272 294.4 272 294.4
- f MC max Hz 50.2 60.5 51 60.5
- f MC min Hz 49.5 59.3 47 59.3
- t MC monitoring s 60 300 30 300
Island Detection On/Off On On Off On
OV Detection On/Off On On On On
Soft Start W/s 1140 - - -
Pac Progression %/min - - - -
P(f)-Mode (1/2/3/Off) Off Off Off Off
- f start Hz 50.2 60.2 50.2 60.2
- f stop Hz - 60.05 - 60.05
- MC f max Hz - - - -
- MC f min Hz - - - -
- MC time s 0 0 0 0
- Reduction %/Hz 40 40 40 40
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Parameter Unit China USA Other Other 60 Hz
- Re-increase %/min 10 - 10 -
Q mode Off Off Off Off
FRT On/Off On Off Off Off
- K factor 0.0 0.0 0.0 0.0
S max SM360TS-SV kVA 369 369 369 369
Pac max SM360TS-SV kW 369 369 369 369
Iac max SM360TS-SV A 666 666 666 666
8 WarrantyGeneral Terms of Guarantee for SolarMax ProductsSolarMax Productions GmbH (herafter SOLARMAX) guarantees the correct function and absence of defects of your SolarMax tools for a particular, device -specific duration of guarantee. This duration of guarantee can be prolonged by an extension of guarantee according to these Terms of Guarantee.
This manufacturer’s guarantee exists in addition to legal warranty obligations of the vendor. In case of a content overlap, the claim under the manufacturer’s guarantee takes precedence, to the extent permitted by law, over the claim from warranty.
For the assertion of warranty claims please contact your vendor.
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1. Basic Guarantee BASIC
The services of the Basic Guarantee are only provided free of charge in countries released by SOLARMAX at the time of installation. Please clarify this with your dealer. You will find a current list of these countries in the appendix or on our homepage. On request we are happy to send you this list.
a) Duration of Guarantee BASIC
String Inverters:
■■ 60 months starting from purchase date, but max. 72 months after delivery of the device by SOLARMAX
Central Inverters:
■■ Series C/S/TS/TS-SV: 24 months from purchase date, but max. 30 months after delivery of device by SOLARMAX
■■ Series RX: 60 months from purchase date, but max. 66 months after delivery of device by SOLARMAX
Accessories:
■■ 24 months from purchase date, but max. 30 months after delivery of device by SOLARMAX■■ Junction-Box 32HT2: 60 months from purchase date, but 72 months after delivery of device by
SOLARMAXDeviating written confirmation from SOLARMAX have priority.
b) Scope of Guarantee BASIC
If a device shows a defect or malfunction within the duration of guarantee and if the conditions for the assertion of warranty as defined below are met, the device or device parts will be repaired or replaced by SOLARMAX free of charge at its discretion within an appropriate period of time, as shown below, provided that this is not disproportionate or impossible.
Free Replacement: This contains the provision of equivalent replacement devices or parts, which can be dispatched step by step against return of the defect devices or device parts or can be also delivered by order.
Free On-Site-Replacement: This contains material cost as well as labor and travel expenses of SOLARMAX staff or staff authorized by SOLARMAX, insofar as it was send to the operation site by SOLARMAX.
Further-reaching claims, especially claiming the replacement of direct and indirect damages, founded by the defect of the device or cost incurred by the implementation and removal or lost profit, are not covered by this guarantee.
2. Assurance of Repair and Replacement
SOLARMAX will provide repair material and replacement devices during the duration of guarantee in its discretion.
If repair material or replacement devices for particular devices are not available anymore, the fol-lowing applies:
SOLARMAX is authorized to install the device, which needs to be replaced, with a comparable device with an equivalent or higher performance.
64
Necessary technical adjustments of the replacement device for the installation of such a replace-ment device are covered by the guarantee for expenditure of time and material to the extent of up to 10 % of the list price of the replacement device.
Not covered by the guarantee are, if need be, a required replacement and a connection of peripheral devices as well as, if need be, required adjustments of surrounding devices of an inverter (such as supply cord, ventilation and safety devices).
SOLARMAX does its level best to minimize the extent of adjustment.
If there is no replacement material available at a reasonable expense, SOLARMAX is authorized to replace the defect device. In this case the above mentioned terms of replacement are applicable.
3. Duration of Guarantee for Device Repair/ Device Replacement
In case of repair or replacement of devices within the scope of the guarantee, the remaining duration of guarantee of the original device applies to the repaired / replaced device.
4. Exclusion of Guarantee Services
Especially in following cases the guarantee claim is cancelled:
■■ In the event of transport damage or external influences■■ In the event of interference, changes, repairs by non-SOLARMAX-authorized staff or on one’s
own■■ In the event of inappropriate use, incorrect operation and installation■■ In the event of neglecting operating, installation and maintenance instructions ■■ In the event of non-compliant surrounding conditions (such as lack of ventilation, humidity, dust
pollution, etc.) ■■ In the event of higher force (such as lightning, overvoltage, water damage, fire etc.)
Not covered by the guarantee are wear parts, especially fuses and overvoltage protection
5. Assertion of Guarantee
For the assertion of the guarantee the SOLARMAX hotline must be contacted by phone or in written form and their instructions must be followed carefully.
You will find the Hotline number for your country on our homepage.
Please hold the series number, the article description, a short description of the defect and the purchase receipt ready.
Transactions in order to solve guarantee cases carried out by the buyer without the coordination with and approval by SOLAR MAX will not be compensated.
In case of neglecting this procedure SOLARMAX reserves the right to decline the delivery of of the guarantee service.
6. Exclusion of Guarantee
SOLARMAX reserves the right to temporarily or finally exclude the guarantee, if the parameters of the plant do not allow a proper function of the devices (e.g. in the event of a parameter as set out in number 4)
The exclusion of guarantee can be cancelled in accordance with SOLARMAX.
Therefore it is necessary to have a written confirmation by SOLARMAX, in order to restart the guarantee terms.
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7. Guarantee Extension
For devices with the Basic Guarantee BASIC the duration of guarantee can be prolonged by purchasing a guarantee extension within the following time periods. An extension for specific devices can be purchased on the basis of limited services. The extensions being available per device can be found on our homepage. The purchase of a guarantee extension will be confirmed by SOLARMAX with a Guarantee Certificate (Series Number of Product).
In case of a replacement this certificate will not be adjusted to the new series number. In this way the guarantee extension stays unaffected.
a) Time Limit for entry into Guarantee Extension
String Inverters / Junction-Box 32HT2: The extension of the guarantee can be purchased within 60 months starting from purchase date, but within max. 72 months after delivery of the device by SOLARMAX.
Central Inverters: The extension of the guarantee can be purchased within 3 months starting from purchase date, but max. 12 months after delivery of the device by SOLARMAX
b) Scope of the Guarantee Extension
The Scope of the Guarantee Extension contains all services of the Basic Guarantee BASIC.
c) Conclusion of a Guarantee Extension
In order to purchase a Guarantee Extension, it is necessary to fully complete and hand in a Gua-rantee Extension form.
The Guarantee Extension is completed with a written confirmation by SOLARMAX, the receipt of the Guarantee Certificate and the payment by the customer.
Deviating written confirmation from SOLARMAX have priority.
8. Conditions after the Extension of the Guarantee
The cost for repair and replacement after the extension of the guarantee period will be charged at cost. SOLARMAX ensures the repair and replacement ability beyond the guarantee period at its own discretion.
9. Applicable Law, Place of Jurisdiction
The Law of the Federal Republic of Germany is applicable, Place of Jurisdiction shall exclusively be Augsburg / Germany, as far as this is permitted by law.
Appendix Country List:
Austria, Belgium, Bulgaria, Czech Republic, Denmark, France, Germany, Greece, Italy, Liechsten-stein, Luxembourg, Netherlands, Portugal, Slovakia, Slovenia, Spain, Sweden, Switzerland, United Kingdom
(Issued 10/2015 – subject to modifications)
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/ 10
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SolarMax Service Center
Please refer to our website for contact details:
www.solarmax.com
www.solarmaxservice.com
Hotline:
DE + 49 3733 507840
CH + 41 315281165
ES + 34 93 2203859
FR + 33 820 420 684
GB + 44 20 38080346
IT + 39 0418520076
Fax + 49 3733 50784 99
Mail [email protected]