Solplanet ASW 05-12kH-T2 Three Phase Hybrid Inverter User Manual

This document provides comprehensive guidance on mounting,
installation, commissioning, configuration, operation,
troubleshooting, and decommissioning of the product. It also covers
the operation of the product user interface.

2. Safety

2.1 Intended Use: Ensure the product is used
only for its intended purpose.

2.2 Important Safety Instructions: Follow all
safety guidelines provided in the manual to prevent accidents or
injuries.

2.3 Symbols on the Label: Familiarize yourself
with the symbols on the product label for safety awareness.

3. Unpacking and Storage

3.1 Scope of Delivery: Check the contents of
the package upon delivery to ensure all components are
included.

3.2 Product Storage: Store the product in a
suitable environment as described in the manual to maintain its
quality.

5. Mounting

5.1 Requirements for Mounting: Review the
mounting requirements before proceeding with the installation.

5.2 Taking Out and Moving the Product: Follow
the instructions for safely handling and relocating the
product.

5.3 Mounting: Install the product securely
following the provided mounting instructions.

7. Commissioning and Operating

7.1 Inspection Before Commissioning: Conduct a
thorough inspection before commissioning to ensure everything is in
order.

7.2 Commissioning Procedure: Follow the
step-by-step procedure outlined in the manual for successful
commissioning.

8. Solplanet APP

8.1 Brief Introduction: Learn about the
Solplanet APP and its features as described in the manual.

FAQ

Q: Who is the target group for this product?

A: The target group includes qualified persons
with specific skills related to inverters, batteries, electrical
devices, and installations. They must adhere to all safety
guidelines and laws mentioned in the document.

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Contents
1 General information ……………………………………3 1.1 About this document………………………………..3 1.2 Product validity……………………………………….3 1.3 Target group…………………………………………..3 1.4 Symbols …………………………………………………4
2 Safety………………………………………………………..5 2.1 Intended use …………………………………………..5 2.2 Important safety instructions……………………5 2.3 Symbols on the label……………………………….8
3 Unpacking and storage………………………………..9 3.1 Scope of delivery…………………………………….9 3.2 Product storage …………………………………… 10
4 Inverter overview………………………………………. 11 4.1 Product description ……………………………….. 11 4.2 Dimensions…………………………………………… 11 4.3 LED indicator ………………………………………..12 4.4 Supported grid types ……………………………. 13 4.5 Interfaces and functions ……………………….. 13 4.6 Basic system solution …………………………… 16 4.7 Energy Management……………………………..20 4.8 Parallel System ……………………………………. 25
5 Mounting ………………………………………………… 31 5.1 Requirements for mounting……………………. 31 5.2 Taking out and moving the product ……….. 32 5.3 Mounting……………………………………………..33
6 Electrical connection…………………………………35 6.1 Connection port description …………………..35 6.2 Connecting additional grounding……………36 6.3 Grid cable connection ………………………….. 37 6.4 EPS Load cable connection ……………………42 6.5 DC connection……………………………………..46 6.6 Battery connection ……………………………….53 6.7 Ai-Dongle connection ……………………………56 6.8 Communication equipment connection…..58
7 Commissioning and operating ……………………68 7.1 Inspection before commissioning ……………68 7.2 Commissioning procedure……………………..68
8 Solplanet APP …………………………………………..69 8.1 Brief introduction…………………………………..69

8.2 Download and install……………………………. 69 8.3 Create an account……………………………….. 69 8.4 Create a plant ……………………………………….71 8.5 Setting parameters ………………………………. 77 8.6 Parallel parameter setting and using ………. 91 8.7 Asymmetrical power output …………………. 94 8.8 Digital output and Heat pump settings ….. 96 8.9 Activated Arc-fault Circuit Interrupter (AFCI) …………………………………………………………………. 98 9 Decommissioning the product ………………….. 101 9.1 Disconnecting the inverter from voltage sources………………………………………………………. 101 9.2 Dismantling the inverter ……………………… 103 10 Technical data …………………………………….. 104 10.1 ASW05kH/06kH/08kH/10kH/12kH-T2 … 104 10.2 ASW05kH/06kH/08kH/10kH/12kH-T2-O107 10.3 ASW08kH/10kH/12kH-T3…………………….110 10.4 ASW08kH/10kH/12kH-T3-O ……………….. 113 10.5 General data ……………………………………… 116 10.6 Protective function …………………………….. 117 11 Troubleshooting …………………………………… 118 12 Maintenance ………………………………………. 120 12.1 Cleaning the contacts of the DC switch .. 120 12.2 Cleaning air inlet and outlet ……………….. 120 13 Recycling and disposal………………………….. 121 14 EU declaration of conformity …………………. 121 15 Service and warranty ……………………………. 121 16 Contact………………………………………………. 122

1 General information
1.1 About this document
This document describes the mounting, installation, commissioning, configuration, operation, troubleshooting and decommissioning of the product as well as the operation of the product user interface. You will find the latest version of this document and further information on the product in PDF format at www.solplanet.net. It is recommended that this document is stored in an appropriate location and be available at all times.
1.2 Product validity
This document is valid for the following models: ASW05kH/06kH/08kH/10kH/12kH-T2 ASW05kH/06kH/08kH/10kH/12kH-T2-O ASW08kH/10kH/12kH-T3 ASW08kH/10kH/12kH-T3-O
For Australia market, this document is valid for the following models: ASW05kH-T2 ASW05kH-T2-O ASW08kH/10kH/12kH-T3 ASW08kH/10kH/12kH-T3-O
1.3 Target group
This document is intended for qualified persons who must perform the tasks exactly as described in this user manual. All installation work must be performed by appropriately trained and qualified persons. Qualified persons must possess the following skills: Knowledge of how an inverter works and is operated. Knowledge of how batteries work and are operated. Training in how to deal with the dangers and risks associated with installing, repairing and using electrical devices,
batteries and installations. Training in the installation and commissioning of electrical devices. Knowledge of all applicable laws, standards and directives. Knowledge of and compliance with this document and all safety information.

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1.4 Symbols DANGER
Indicates a hazardous situation which, if not avoided, will result in death or serious injury.
WARNING
Indicates a hazardous situation which, if not avoided, could result in death or serious injury.
CAUTION
Indicates a hazardous situation which, if not avoided, could result in minor or moderate injury.
NOTICE
Indicates a situation which, if not avoided, can result in property damage.
Information that is important for a specific topic or goal, however not related to safety.

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2 Safety

2.1 Intended use
The product is a transformerless hybrid inverter with 2 or 3 MPP trackers and a battery connection that feeds the direct current of the PV array into the connected battery or converts it to grid-compliant three-phase current and then feeds it into the utility grid. The product also can convert the DC current supplied by the battery into grid-compliant threephase current. The product also can convert the AC current supplied by the grid into battery current.
The product has a backup function that can continue to supply selected circuits with power from the battery or PV system in the event of a grid fault.
The product also can convert the direct current supplied by the battery into grid-compliant threephase current.The product is intended for indoor and outdoor applications.
The product must only be connected with PV modules of protection class II (in accordance with IEC 61730, application class A). Do not connect any sources of energy other than PV modules and batteries to the product.
The product is not equipped with an integrated transformer and therefore has no galvanic isolation. The product must not be operated with PV modules which require functional grounding of either the positive or negative PV conductors. This can cause the product to be irreparably damaged. The product may be operated with PV modules with frames that require protective earthing.
All components must remain within their permitted operating ranges and their installation requirements at all times.
Use the product only in accordance with the information provided in the user manual and with the locally applicable standards and directives. Any other application maycause personal injury or damage to property.
The product must only be operated in connection with an intrinsically safe lithium-ion battery approved by AISWEI. The entire battery voltage range must be completely within the permissible input voltage range of the product.
The product must only be used in countries for which it is approved by AISWEI and the grid operator. Knowledge of all applicable laws, standards and directives.
Knowledge of and compliance with this document and all safety information. The type label must be permanently attached to the product and must be in a legible condition. This document does not replace any regional, state, provincial, federal or national laws, regulations or standards that apply
to the installation, electrical safety and use of the product.

2.2 Important safety instructions

The product has been designed and tested strictly according to the international safety requirements. As with all electrical or electronical devices, there are residual risks despite careful construction. To prevent personal injury and property damage and to ensure long-term operation of the product, read this section carefully and observe all safety information at all times.
DANGER

Danger to life due to high voltages of the PV array or the battery
The DC cables connected to the battery or the PV array may be live. Touching the DC conductors or the live components can cause lethal electric shocks. If you disconnect the DC connectors from the product under load, an electric arc may occur leading to electric shock and burns.

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Do not touch non-insulated cable ends. Do not touch the DC conductors. Do not touch any live components of the product. Do not open the product. Observe all safety information provided by the battery manufacturer. All work on the product must only be carried out by qualified personnel who have read and fully understood all safety information
contained in this document and the user manual. Disconnect the product from all voltage and energy sources and ensure it cannot be reconnected before working on the product. Wear suitable personal protective equipment for all work on the product.
DANGER
Danger to life due to electric shock when touching live components in backup mode!
Despite the AC breaker and the PV switch of the inverter being disconnected, parts of the system may still be live when the battery is switched on due to backup mode. Do not open the product. Disconnect the product from all voltage and energy sources and ensure it can not be reconnected before working on the product.
DANGER
Danger to life due to fire or explosion when batteries are fully discharged!
Danger to life due to fire or explosion when batteries are fully discharged. Ensure that the battery is not fully discharged before commissioning the system. Contact the battery manufacturer for further information if the battery is fully discharged.
DANGER
Danger to life due to burns caused by electric arcs through short-circuit currents!
Short-circuit currents in the battery can cause heat accumulation and electric arcs if the battery is short circuited or incorrectly installed. Heat accumulation and electric arcs may result in lethal injuries due to burns. Disconnect the battery from all voltages sources prior to performing any work on the battery. Only use properly insulated tools to prevent accidental electric shock or short circuits during installation. Observe all safety information of the battery manufacturer.
DANGER
Danger to life due to electric shock when touching live system components in case of a ground fault!
If a ground fault occurs, parts of the system may still be live. Touching live parts and cables may result in death or lethal injuries due to electric shock. Disconnect the product from voltage and energy sources and ensure it cannot be reconnected before working on the device. Only touch the cables of the PV modules on their insulation. Do not touch any parts of the substructure or frame of the PV array. Do not connect PV strings with ground faults to the product.

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WARNING
Danger to life due to electric shock from destruction of the measuring device due to overvoltage! Overvoltage can damage a measuring device and result in voltage being present in the enclosure of the measuring device. Touching the live enclosure of the measuring device results in death or lethal injuries due to electric shock. Only use measuring devices with a measurement span higher than the DC input voltage range
CAUTION
Risk of burns due to high temperature! Some parts of the enclosure can become hot during operation. During operation, do not touch any parts other than the enclosure lid of the product.
CAUTION
Risk of injury due to weight of product! Injuries may result if the product is lifted incorrectly or dropped while being transported or mounted. Transport and lift the product carefully. Take the weight of the product into account. Wear suitable personal protective equipment for all work on the product.
NOTICE
Damage to the inverter due to electrostatic discharge. Internal components of the inverter can be irreparably damaged by electrostatic discharge. Ground yourself appropriately before touching any component.
The country grid code set must be set correctly. If you select a country grid code set which is not valid for your country and purpose, it can cause a disturbance within the PV system and lead to problems with the grid operator. When selecting the country grid code set, you must always observe the locally applicable standards and directives as well as the properties of the PV system (e.g., PV system size, gridconnection point). If you are not sure which standards and directives are valid for your country or purpose, contact the grid operator.

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2.3 Symbols on the label
Beware of a danger zone This symbol indicates that the product must be additionally grounded if additional grounding or equipotential bonding is required at the installation site.
Beware of high voltage and operating current The inverter operates at a high voltage and current. Work on the product must only be carried out by skilled and authorized personnel.
Beware of hot surfaces The inverter can get hot during operation. Avoid contact during operation.
WEEE Designation Do not dispose of the product together with household waste. Dispose the product in accordance with local disposal regulations for electronic waste.
CE marking The product complies with the requirements of the applicable EU directives.
Certification mark The product has been tested by TUV and got the quality certification mark..
RCM Mark The product complies with the requirements of the applicable Australian standards.
Capacitor discharge Danger to life due to high voltages in the inverter. Do not touch live parts for at least 10 minutes after disconnection from the power sources.
Observe the documentation Read and understand all documentation supplied with the product.

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3 Unpacking and storage
3.1 Scope of delivery
Check the scope of delivery for completeness and any visible external damage. Contact your distributor if the scope of delivery is incomplete or damage.

Object A B C D
E
F

Description Inverter
Wall Bracket AC connector
Teminal Ai-Dongle(WLAN/LAN)
Battery connector
Crimp contact (6mm²)
Battery connector
Crimp contact (10mm²)

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K
Type/Quantity 1 1 1 5 1
Socket: PV-KBT4-EVO ST/6I Plug: PV-KST4-EVO ST/6I PV-BP4-EVO 2/6 PV-SP4-EVO 2/6
Socket: PV-KBT4-EVO ST/10II Plug: PV-KST4-EVO ST/10II PV-BP4-EVO 2/10 PV-SP4-EVO 2/10

L
1 1 1 1 1 1 1 1 9

EPS Load connector G
Teminal

DC connector

Document

Smart meter

Fastener package

Communication terminal package

ASW05-12kH-T2-O 0
ASW08-12kH-T3-O ASW05-12kH-T2 1 ASW08-12kH-T3
ASW05-12kH-T2-O 0
ASW08-12kH-T3-O ASW05-12kH-T2 5 ASW08-12kH-T3 ASW05-12kH-T2 2
ASW05-12kH-T2-O ASW08-12kH-T3 3
ASW08-12kH-T3-O 1 1 1 1

3.2 Product storage
Suitable storage is required if the inverter is not installed immediately: Store the inverter in the original packing case. The storage temperature must be between -30°C to +70°C, and the storage relative humidity must be between 0 and 100%,
non-condensing. The packing with the inverter shall not be tilted or inverted. The product must be fully inspected and tested by professionals(Refer to section 1.3) before it can be put into operation,
if it has been stored for half a year or more.

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4 Inverter overview
4.1 Product description

Figure shown here is for reference only. The actual product received may differ

Object 1
2 3 4
5 6 7 8

Name Mounting ears
Inverter fixed point Labels Handles
DC wiring area Communication wiring area AC wiring area Display area

Description
Two ears hang the inverter onto the mounting-bracket. Two points, used for the fixed connection between the inverter and the mounting-bracket. Warning symbols, nameplate, and QR code. Two handles, move the product and hang the inverter onto the mounting-bracket.
DC switches, DC terminals and BAT terminals.
WIFI terminals and communication cover. GRID terminals and EPS Load terminals. LED indicator and display panel.

4.2 Dimensions

Unitmm

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4.3 LED indicator

Function

LED

Description

Glowing

The product operates normally and the solar energy is available.

SOLAR

Flashing Off

The product is self-checking automatically, or the firmware is updating. The solar energy is not available.

Glowing

The product operates normally and the battery energy is available.

BAT

Flashing

The product is self-checking automatically, or the firmware is updating, or the SOC of the battery is low.

Off

The battery energy is not available.

Yellow Glowing

The communication with the Ai-Dongle has failed.

ERR

Yellow Flashing Red Glowing

There is a warning fault, the warning message and the corresponding event number will be displayed on the product user interface.
There is an error fault. The Error message and the corresponding event number will be displayed on the product user interface.

Off

The product is operating normally.

White Glowing

The EPS port of the product operates with the loads.

White Flashing

The EPS port of the product operates without the loads.

EPS

Red Glowing

The EPS port of the product has failed.

Red Flashing

The EPS port of the product operates with overload.

Off

The EPS port of the product stop operation.

White Glowing

The product connects to the Grid and feeds the solar energy into the utility grid.

GRID

White Flashing Red Glowing

The product doesn’t connect to the grid and operates as an off-grid mode. The product disconnects from the Grid due to a fault.

Off

The product stop operation.

For safety reasons, EPS LED white flash when there is no load or when the load power is low.

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4.4 Supported grid types
The grid structures supported by the product is TN-S, TN-C, TN-C-S, TT, as shown in the figure below:

For the TT grid structure, the effective value of the voltage between the neutral wire and the ground wire must be less than 20V.
4.5 Interfaces and functions
The product is equipped with the following interfaces and functions:
Ai-Dongle The product is equipped with an Ai-Dongle as standard, which provides a user interface for configuring and monitoring the product. The Ai-Dongle can connect to the Internet via WLAN or the Ethernet cable. If you don’t want to use Ai-Dongle, the Solplanet communication products or the third-party monitor device can be chosen.
RS485 Interface The product equipped with several RS485 interfaces. Some RS485 interfaces connected through RJ45 ports. Some RS485 interfaces connected through terminal block. RJ45-1 and RJ45-2 ports (see section 6.8.1): Two RS485 interfaces used to the product parallel operation (see section 4.1). The monitoring information of all the slave inverters can exchange with the master inverter through the RS485 interfaces. And the master inverter transfers the monitoring information to Internet through the Ai-Dongle. RJ45-3 port (see section 6.8.1): This RS485 interface used to connect the product to the third-party monitor device. If you don’t want to use Ai-Dongle, the third-party monitor device can be used. Terminal block 2 (see section 6.8.1): This RS485 interface (Pin1 and Pin2) used to connect the external smart meter. If the smart meter be chosen to replace the current transformer, the smart meter can connect to this RS485 interface.
RS485/CAN (Controller Area Network) Interface The product equipped with several RS485/CAN interfaces. The CAN interfaces and RS485 interfaces connected through one RJ45 ports.

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RJ45-4 port (see section 6.8.1): This RS485/CAN interface used to connect the BMS (Battery Manage System) of the battery (see section 6.8.1). If the communication interface of the BMS is CAN interface, the pins for CAN interface can be chosen to connect. If the communication interface of the BMS is RS485 interface, the pins for RS485 interface can be chosen to connect. RJ45-5 and RJ45-6 ports (see section 6.8.1): Two RS485/CAN interfaces used to the product parallel operation (see section 4.1). The control information can be exchanged between the master inverter and the slave inverter through the RS485/CAN interfaces. Both the pins for RS485 interface and CAN interface shall be chosen to connect.
Modbus RTU The product is equipped with a Modbus interface. If the third-party communication device also complies with AISWEI Modbus protocol, which can be connected to this product.
Export active power control The product is equipped with the export active power limit function, so as to meet the requirements of some national standards or grid standards for limiting the output power at the grid connection point. The export active power control solution measures the active power at the point where the customer’s installation is connected to the distribution system (point of grid connection) and then uses this information to control the inverter’s output active power in order to prevent the export active power to the distribution system from exceeding the agreed export capacity. The product is delivered with the current transformers as standard. The current transformers can be used to measure the export active power. The communication of the current transformers can be connected to the product through RS485 (see section 6.8.1, Terminal 2). And the current transformer also can be replaced by the smart meter. The smart meter that can be used with this product must be approved by AISWEI. For more information about the smart meter, please contact the service.
Multifunction Relay The product is equipped with two multifunction relays as standard. The multifunction relays can be configured for the operating mode used by a particular system. For more information, please contact AISWEI service.
Temperature Senser Interface The product is equipped with one temperature senser interface (see section 6.8.1). If the temperature of the battery need be monitored, the external senser can be connected.
The communication interface for external central grid protection device The product is equipped with one communication interface (see section 6.8.1) to connect the external central grid protection device. For more information, please contact with AISWEI service.
Inverter demand response modes (DRED) The product shall detect and initiate a response to all supported demand response commands according to the standard AS/NZS 4777.2. The product only supports the demand response mode DRM 0. The interaction with demand response enabling device (DRED) can be connected to the terminal block 3 (see section 6.8.1). The Pin 5 and Pin 6 of the terminal block 3 represents the REF GEN/0 and COM LOAD/0.

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Ripple control receiver interface The product is equipped with one interface to connect Ripple Control Receiver device (see section 6.8.1).
Current transformer interface The current transformers can be used to measure the export active power and control the export active power at the point of grid connection. The three current transformers can be connected to terminal block 4 (See section 6.8.1).
Back-up function The inverter is equipped with a back-up function which also called as an emergency power supply (EPS). The back-up function ensures that the inverter forms a three-phase back-up grid that uses energy from the battery and the PV system that is directly connected to the inverter to supply the critical load in the event of a utility grid failure. In the event of a grid failure, the product disconnects from the grid. The product provides a standalone grid and the backup loads, which connect to EPS connector, continue to be supplied by the energy stored in the battery and the PV modules. The charging of the battery is ensured by the existing PV system during back-up operation. As soon as the utility grid is available again, the product will automatically connect to the grid and the loads are supplied with energy from the utility grid.
Earth fault alarm This product complies with IEC 62109-2 clause 13.9 for earth fault alarm monitoring. If an Earth Fault Alarm occurs, the red color LED indicator will light up. At the same time, the error code 38 will be sent to the Solplanet Cloud.
Arc-fault Circuit Interrupter (AFCI) function The arc-fault circuit interrupter (AFCI) integrated in Solplanet’s inverter selects a specific medium frequency band to detect genuine DC arcs. When the arc-fault circuit interrupter (AFCI) is enabled in the inverter, the PV system continuous monitors for electric arcs. If a current phenomenon typical of electric arcs is detected, the inverter immediately stops the feed-in operation and reports the event. This interruption of the feed-in operation stops the current flow in the DC circuit, effectively extinguishing the electric arc.

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4.6 Basic system solution
The product is a high-quality inverter which can convert solar energy to AC energy and store energy into battery. The product can be used to optimize self-consumption, store in the battery for future use or feed into public grid. The basic application of this product as follow:

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Object Description

Remark

A PV String

The product supports to connect the monocrystalline silicon, polycrystalline silicon, and thinfilm without grounding.

B Hybrid inverter C Smart meter

ASW H-T2 and ASW H-T3 series products have an EPS port. ASW H-T2-O and ASW H-T3-O series products doesn’t have an EPS port.
The smart meter is the central device responsible for energy management. The smart meter also can be replaced by three current transformer which can communication with inverter directly.

D Utility grid

The product can connect to TN and TT grounding system grid.

E Battery system F Ai-Dongle G EPS Load H Normally load

The product must only be operated in connection with an intrinsically safe lithium-ion battery system approved by AISWEI.
The Ai-Dongle supports Ethernet communication and WLAN communication. It is not recommended to use both communication methods at the same time.
The EPS load directly connected to the EPS port of the inverter. The EPS load can be power supplied by the inverter after the utility grid is failure.
The normally load directly connected to utility grid. The norm- ally load will be power off after the utility grid is failure.

I Router

The product can connect to router through Wi-Fi signal or Ethernet cable.

J Internet

The monitor information can transfer to Cloud Server through Internet.

K Cloud server

The monitor information is stored at cloud server.

L Smart phone

The APP can be installed on the smart phone and then review the monitor information.

M Computer

The monitor information also can be review on the computer.

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The system diagram of this product as follow:
For Australia and New Zealand, the neutral cable of On-grid side and EPS side must be connected together according to the wiring rules AS/NZS 3000. Otherwise the EPS function will not work.

For other countries, the following diagram is an example for grid systems without special requirement on wiring connection.

Current transformer connection and smart meter connection refer to 6.8.3 and 6.8.4.

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The wiring system of the basic application is an example for grid systems without special requirement:

5kW 1
2 20A/400V
3 AC Breaker
4
5

6kW

8kW 63Amax/600v DC Breaker

10kW

25A/400V AC Breaker

32A/400V AC Breaker

Depends on household

12kW
40A/400V AC Breaker

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4.7 Energy Management
The energy management mode depends on PV energy and user’s preference. There are four energy management mode can be chosen. Self-Consumption mode The photovoltaic energy is preferentially used by local load to improve the self- consumption rate and self-sufficiency rate. The energy management during daytime: Case 1: PV power generation is lower than the load power consumption, and the energy of the battery is not available.

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Case 2: PV power generation is lower than the load power consumption, and the energy of the battery is available. Case 3: PV power generation is larger than the load power consumption.

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The energy management during night: Case 1: The energy of the battery is available.
Case 2: The energy of the battery is not available.

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Reserve mode The battery is a back-up energy storage device. The battery always charged by PV power if it is not full charged. The battery discharge only when the utility grid loss. Case 1: The energy of the battery is not full charged.
Case 2: The energy of the battery is full charged, even at night.

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Case 3: The battery discharge when the utility grid loss.

Off-grid mode If the power grid is too weak and the inverter operating unstablely, it is recommended that the customer switch to off grid mode to achieve stable power supply. We will update this chapter with more details in an upcoming release.
Custom mode In user-defined mode, customers can set their own charging and discharging time periods, and the charging and discharging power can be set by themselves in the APP. We will update this chapter with more details in an upcoming release.
Time of use mode If user choose load first, then inverter will operate in self-consumption mode when grid charge disable, and if grid charge enable the inverter will operate in back-up mode (battery SOC below the set point) or self-consumption mode(battery SOC above the set point) If user choose battery first, the PV input power will charge battery firstly when grid charge disable, and if grid charge enable ,the inverter will operate in back-up mode(battery SOC below the set point) or self-consumption mode(battery SOC above the set point)
We will update this chapter with more details in an upcoming release.

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4.8 Parallel System
4.8.1 Grid parallel
The hybird inverter can operate as a parallel system. The system can even work when the utility grid is loss occasionally.

A Master Inverter D Grid port

B Slaver Inverter 1 E EPS load port

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C Slaver Inverter N F Communication cable
25

Hybrid inverters with the same model can be connected in parallel in grid port. the EPS load should be independent of each inverter and the battery should be same model, show as follows.

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4.8.2 Grid and EPS parallel
There is another parallel solution: Grid and EPS parallel, which can support larger EPS load and can operate even when grid loss.

A Master Inverter D Grid port

B Slaver Inverter 1 E EPS load port

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C Slaver Inverter N F Communication cable
27

Hybrid inverters with the same model can be connected in parallel in EPS port and grid port at the same time, the battery should be same model, show as follows:

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CAUTION
Risk of damage to the inverters!
Due to incorrect connection, the inverter will be permanently damaged The EPS phase sequence of all inverters in the parallel system must be completely consistent when Multi machine EPS in parallel
enable, strongly recommend measure each PIN of EPS and Grid connector before commission, make sure the same phase PIN of master and slaver inverter is connected together.

The parallel system supports the following meters . Customer can install the different type meter which can meet AC bus current requirement. CT should not used in parallel system. The smart meter should connect as 3P4W wiring refer to smart meter User Manual. Recommend purchasing smart meter from Soplanet, some functions will be limited if purchased from other sources.

Manufacturer EASTRON EASTRON EASTRON CHINT CHINT

Model
SDM630-Modbus V2 SDM630MCT V2
SDM630MCT 40mA (PV)DTSU666 3×230/400V 5(80)A 4P (PV)DTSU666 3*220/380V 250A/50mA 4P Modbus

Max current

CTs

100A

250A

3*ESCT-T24 250A/1A

120A

3*ESCT-TA16 120A/40mA

80A

250A

3*CT NCTK-24 250a/50mA

NOTICE
Damage to the inverter due to wiring error.
Parallel system wiring must be performed as required, otherwise the product will not work properly or even be damaged.
The phase sequence of the grid-side wiring of all parallel inverters must be completely consistent. If EPS is parallel , the EPS phase sequence also must be completely consistent.
The smart meter is connected to the AC bus, that is, when multiple units are running in parallel, the system share one smart meter, and the smart meter communication line is connected to the master inverter. The entire parallel system can only use one meter.
Ai-dongle and smart meter must be connected to master inverter. Use Ethernet cables for inverter communication to connect multiple inverters in series. The length of a single Ethernet cable should
less than 20m. The wire sequence is the same at both ends of the ethernet cable , The two communication cables cannot be confused. After the wiring is completed, the empty communication ports of the first and last inverter are inserted into a RJ45 port terminal resistance in the accessory bag. Select the battery type in the APP of master inverter. The process steps are the same as the single inverter settings. Please refer to Chapter 8.4. Multi machine EPS in parallel in APP is for Grid and EPS parallel function , for Grid parallel function, this option must be “off”. The inverters in a parallel system can be left unconnected to the battery. But in EPS parallel mode, the Master inverter must be connected to the battery.

NOTICE

Adding inverters or deleting inverters in the parallel system requires re-scanning the inverter (the network cable and 120ohm matching resistor are connected according to the inverter).
Replace the master and slave inverters on the premise that both the inverters in the parallel system are good: cut off all inverter power, move the stick and meter terminal to new master inverter, and connect the Ethernet cable and 120ohm matching resistor along with the new master inverter, and then power on, wait until the green light on the stick is always on, click to scan the

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inverter. After the new system is scanned out, the replacement is completed. When the master inverter of the parallel system is broken and all inverters are powered off, replace the master inverter: power off
all the inverter, move the stick and meter to new master inverter, the Ethernet cable and 120ohm matching resistor are also connected with the replacement of the master inverter, and then all power on, wait for the green light on the stick to turn on, click to scan the inverter. After the new system is scanned out,. At this time, the replacement is completed.
NOTICE
In a parallel system, if NS-protection is triggered when the system is working off-grid mode and an exception occurs after the system recovers, need to rescan the parallel system with the app.

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5 Mounting
5.1 Requirements for mounting DANGER
Danger to life due to fire or explosion Despite careful construction, electrical devices can cause fires. This can result in death or serious injury. Do not mount the product in areas containing highly flammable materials or gases. Do not mount the inverter in areas where there is a risk of explosion. The ambient temperature is recommended below 40°C to ensure optimal operation. A solid support surface must be available (e.g., concrete or masonry). Ensure that the installation surface is solid enough
to bear four times the weight. When mounted on drywall or similar materials, the product emits audible vibrations during operation which could be perceived as annoying. The mounting location must be inaccessible to children. The mounting location should be freely and safely accessible at all times without the need for any auxiliary equipment (such as scaffolding or lifting platforms). Non-fulfillment of these criteria may restrict servicing. The mounting location must not be exposed to direct solar irradiation. If the product is exposed to direct solar irradiation, the exterior plastic parts might age prematurely and overheating might occur. When becoming too hot, the product reduces its power output to avoid overheating.
Never install the inverter horizontally, or with a forward / backward tilt or even upside do- wn. The horizontal installation can result in damage to the inverter.

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Maintain the recommended clearances to wall as well as to other inverters or objects.

In case of multiple inverters, reserve specific clearance between the inverters.

The product should be mounted such that the LED signals can be read off without difficulty. The DC load-break switch of the product must always be freely accessible.
5.2 Taking out and moving the product
Open the inverter packaging box, take the inverter out of the packaging box, and place the inverter at the designated installation location.
CAUTION
Risk of injury due to the weight of the product! The net weight of this product is over 26kg. If the inverter is lifted incorrectly during the installation, it may fall down and cause injury or equipment damage. Transport and lift the product carefully. Take the weight of the product into account. Wear suitable personal protective equipment for all work on the product.

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5.3 Mounting
Step 1 Align the mounting-bracket horizontally on the wall with the arrow upwards. Mark the position of the drill hole. Set the wall mounting bracket aside and drill the marked holes with the diameter of 10mm. The depth of the holes should be about 70 mm. Keep the hammer drill bit perpendicular to the wall to avoid drilling inclined.

Step 2 Hammer the plastic expansion pipe slowly into the drilled hole. Step 3 Align the mounting-bracket with the hole position and use the tapping nail to fix the hanging plate.

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Step 4 Hang the inverter to the mounting-bracket and ensure that the mounting ears perfectly engage with the mountingbracket.
Step 5 Fix the inverter with screws.

Complete the installation. 34

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6 Electrical connection
6.1 Connection port description

Figure shown here is for reference only. The actual product received may differ

Object 1 2 3 4 5 6 7 8

Description Battery Port DC-switch PV Input Ai-Dongle Communication ports AC connector EPS Load connector Additional grounding screw

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For the Australian market, the DC switch is shown below:

6.2 Connecting additional grounding

The inverter is equipped with a grounding conductor monitoring device. This grounding conductor monitoring device detects when there is no grounding conductor connected and disconnects the inverter from the utility grid if this is the case. Hence the product does not require an additional grounding or equipotential bonding when operating.

If the grounding conductor monitoring function is deactivated or the additional grounding is required by locally standard, you can connect additional grounding to the inverter.

Requirements for the secondary protection ground cable:

Item 1 2 3

Description
Screw OT/DT terminal Yellow and green ground cable

Note
Specifications M5, complimentary Specifications M5, complimentary Same as the PE wire in the AC cable.

Procedure:
Step 1 Strip the grounding cable insulation. Insert the stripped part of the grounding cable into the ring terminal lug and crimp using a crimping tool.

1: Heat shrink tubing

2: OT/DT terminal (M5)

Step 2 Remove the screw on the ground terminal, insert the screw through the OT/DT terminal, and lock the terminal using a wrench.

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Step 3 Apply paint to the grounding terminal to ensure corrosion resistance. Complete the installation.
6.3 Grid cable connection
6.3.1 Requirements for the Grid connection
Cable Requirements The cable must be dimensioned in accordance with the local and national directives for the dimensioning of cables. The requirements for the minimum wire size derive from these directives. Examples of factors influencing cable dimensioning are: nominal AC current, type of cable, routing method, cable bundling, ambient temperature and maximum desired line losses.

Item A B C D

Description External diameter Copper cable conductor cross-section Insulation stripping length Sheath stripping length

Value 12.5…17.5 mm 4~6 mm² 10 mm 40 mm

Residual current protection
The product is equipped with an integrated universal current-sensitive residual current monitoring unit inside. Hence the product does not require an external residual-current device when operating.

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If local regulations require the use of a residual-current device, please install a type A residual-current protection device with a protection limit of not less than 300mA.
Overvoltage category The inverter can be used in grids of overvoltage category III or lower in accordance with IEC 60664-1. That means that the product can be permanently connected to the grid-connection point of a building. In case of installations with long outdoor cable route, additional measures to reduce overvoltage category IV to overvoltage category III are required.
AC circuit breaker In PV systems with multiple inverters, protect each inverter with a separate circuit breaker. This will prevent residual voltage being present at the corresponding cable after disconnection. No consumer load should be applied between AC circuit breaker and the inverter. The selection of the AC circuit breaker rating depends on the wiring design (wire cross-section area), cable type, wiring method, ambient temperature, inverter current rating, etc. Derating of the AC circuit breaker rating may be necessary due to self-heating or if exposed to heat. The maximum output current and the maximum output overcurrent protection of the inverters can be found in section 10 “Technical data”.
Grounding conductor monitoring The inverter is equipped with a grounding conductor monitoring device. This grounding conductor monitoring device detects when there is no grounding conductor connected and disconnects the inverter from the utility grid if this is the case. Depending on the installation site and grid configuration, it may be advisable to deactivate the grounding conductor monitoring. This is necessary, for example, in an IT system if there is no neutral conductor present and you intend to install the inverter between two line conductors. If you are uncertain about this, contact your grid operator or AISWEI.
Safety in accordance with IEC 62109 when the grounding conductor monitoring is deactivated. In order to guarantee safety in accordance with IEC 62109 when the grounding conductor monitoring is deactivated, carry out the following measure. Connect an additional grounding that has at least the same cross-section as the con- nected grounding conductor to the AC cable.
This prevents touch current in the event of the grounding conductor on the AC cable failing.
6.3.2 Assembling the grid connectors
Step 1 Switch off the miniature circuit-breaker or the switch of every energy sources and secure it against being inadvertently switched back on.

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Step 2 Split grid connector. Step 3 Crimp the terminals with crimping pliers.

Crimping tool selection and crimping requirements are shown in the following figure

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Step 4 Set the parts on the cable, insert the terminal holes in sequence. Crimp the wire with an inner hexagon screwdriver and screw the torque 1.2+/-0.1N·m.

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Step 5 Insert the main body into the rubber core and hear the “click” sound.

Step 6 Tighten the nut with an open-ended wrench (torque 2.5±0.5 N·m).
6.3.3 Connecting the grid connectors
Step 1 Remove the dust cover.

Step 2 The installation arrow indicates insertion the female connector, and hear the “click” sound.

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Complete the installation.
6.4 EPS Load cable connection
6.4.1 Requirements for the EPS Load connection
For EPS Load connection requirements, refer to “6.3.1 EPS Load Connection Requirements” for details.
6.4.2 Assembling the EPS Load connectors
Step 1 Switch off the miniature circuit-breaker or the switch of every energy sources and secure it against being inadvertently switched back on.

Step 2 Split grid connector.

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Step 3 Crimp the terminals with crimping pliers. Crimping tool selection and crimping requirements are shown in the following figure

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Step 4 Set the parts on the cable, insert the terminal holes in sequence. Crimp the wire with an inner hexagon screwdriver and screw the torque 1.2+/-0.1N·m.

Step 5 Insert the main body into the rubber core and hear the “click” sound.

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Step 6 Tighten the nut with an open-ended wrench (torque 2.5±0.5N·m).
6.4.3 Connecting the Back Load connectors
Step 1 Remove the dust cover.

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Step 2 The installation arrow indicates insertion the female connector, and hear the “click” sound.

Complete the installation.
6.5 DC connection
6.5.1 Requirements for the DC connection
Requirements for the PV modules per input: All PV modules should be of the same type. All PV modules should be aligned and tilted identically. On the coldest day based on statistical records, the open-circuit voltage of the PV modules must never exceed the
maximum input voltage of the inverter. The maximum input current per PV module must be maintained and must not exceed the through fault current of the DC
connectors. The connection cables to the inverter must be equipped with the connectors included in the scope of delivery. The thresholds for the input voltage and the input current of the inverter must be adhered to. The positive connection cables of the PV modules must be equipped with the positive DC connectors. The negative
connection cables of the PV modules must be equipped with the negative DC connectors.
6.5.2 Assembling the DC connectors
DANGER
Danger to life due to electric shock when live components or DC cables are touched When exposed to light, the PV modules generate high DC voltage which is present in the DC cables. Touching live DC cables results in death or lethal injuries due to electric shock. Do not touch non-insulated parts or cables. Disconnect the product from voltage sources and ensure it cannot be reconnected before working on the device. Wear suitable personal protective equipment for all work on the product.

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For connection to the inverter, all PV module connection cable must be fitted with the DC connectors provided. There may be one of two different type DC connector shipped. Assemble the DC connectors as described in the following.
Type 1 DC connector: Assemble the DC connectors as described below. Be sure to observe the correct polarity. The DC connectors are marked with the symbols “+” and “-“.

Cable requirements:

Item

Description

Cable type

External diameter

Conductor cross-section

Number of copper wires

The rated voltage

Procedure: Step 1 Strip 12 mm off the cable insulation.

Value PV cable 5-8 mm 2.5-6 mm² At least 7 1100v

Step 2 Crimp the contacts with the corresponding cables. Crimping tool: PV-CZM-61100.

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If the stranded wire is not visible in the chamber, the cable is not correctly inserted and the connector must be reassembled. To do this, the cable must be removed from the connector.
Release the clamping bracket. To do so, insert a screwdriver (blade width: 3.5mm) into the clamping bracket and pry the clamping bracket open.
Remove the cable and go back to step 2. Step 3 Push the swivel nut up to the thread and tighten the swivel nut. (SW15, Torque: 2.0Nm)
Type 2 DC connector: Assemble the DC connectors as described in the following. Assemble the DC connectors as described below. Be sure to observe the correct polarity. The DC connectors are marked with the symbols “+” and “-“.

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Cable requirements:

Item

Description

Cable type

External diameter

Conductor cross-section

Number of copper wires

The rated voltage

Procedure: Step 1 Strip 12 mm off the cable insulation.

Value PV1-F, UL-ZKLA or USE2 5-8 mm 2.5-6 mm² At least 7 1100v

Step 2 Assemble the cable ends with the crimping pliers.

Step 3 Lead the cable through cable gland, and insert into the insulator until it snaps into place. Gently pull the cable backward to ensure firm connection. Tighten the cable gland and the insulator (Torque 2.5-3Nm).

Step 4 Ensure that the cable is correctly positioned.

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6.5.3 Connecting the PV module
DANGER
Danger to life due to high voltages in the inverter When exposed to light, the PV modules generate high DC voltage which is present in the DC cables. Touching live DC cables results in death or lethal injuries due to electric shock.. Before connecting the PV array, ensure that the DC switch is switched off and that it cannot be reactivated. Do not disconnect the DC connectors under load.
NOTICE
The inverter can be destroyed by overvoltage! If the voltage of the strings exceeds the maximum DC input voltage of the inverter, it can be destroyed due to overvoltage. All warranty claims become void. Do not connect strings with an open-circuit voltage greater than the maximum DC input voltage of the inverter. Check the design of the PV system.
Procedure: Step 1 Ensure that the individual miniature circuit-breaker is switched off and ensure that it cannot be accidentally reconnected.

Step 2 Ensure that the DC switch is switched off and ensure that it cannot be accidentally reconnected. Step 3 Ensure that there is no ground fault in the PV array. Step 4 Check whether the DC connector has the correct polarity. If the DC connector is equipped with a DC cable having the wrong polarity, the DC connector must be reassembled. The DC cable must always have the same polarity as the DC connector. Step 5 Ensure that the open-circuit voltage of the PV array does not exceed the maximum DC input voltage of the inverter. Step 6 Connect the assembled DC connectors to the inverter until they audibly snap into place.

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NOTICE
Do not operate the DC switch during the operation of the inverter, otherwise it will cause the inverter to stop or even damage the inverter.
Type 1 DC connector: Connect the assembled DC connectors to the inverter.
For unused DC connectors, push down the clamping bracket and push the swivel nut up to the thread. Insert the DC connectors with sealing plugs into the corresponding DC inputs on the inverter.

Insert the DC connectors with sealing plugs into the corresponding DC inputs on the inverter.

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Type 2 DC connector: Connect the assembled DC connectors to the inverter.
For unused DC connectors, push down the clamping bracket and push the swivel nut up to the thread. Insert the DC connectors with sealing plugs into the corresponding DC inputs on the inverter.

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Check the positive and negative polarity of the PV strings, and connect the PV connectors to corresponding terminals only after ensuring polarity correctness. (The graph uses the type 2 connector as an example only.)

Step 7 Ensure that all DC connectors and the DC connectors with sealing plugs are securely in place. Complete the installation.
6.6 Battery connection
6.6.1 Requirements for the Battery connection
Assemble the Battery connectors as described in the following. Before connect battery, it is important to make sure the battery is in Hybrid-battery compatibility list,please download the list in the webside:https://solplanet.net/products/asw-5-12k-h-t2-t3-series/.
For Australia market, please download the list in the webside: https://solplanet.net/au/products/asw-5-12k-h-t2-t3-series/. Assemble the Battery connectors as described below. Be sure to observe the correct polarity. The Battery connectors are marked with the symbols “+” and “-“.

Cable requirements:

Item

Description

External diameter

Conductor cross-section

Value 6.4-8.5 mm 6mm²/10AWG or 10 mm²/8AWG

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Number of copper wires

The rated voltage

6.6.2 Assembling the Battery connectors

Procedure: Step 1 Strip 6-7.5 mm off the cable insulation.

At least 7 1100v

Step 2 Assemble the cable ends with the crimping pliers.

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Step 4 Ensure that the cable is correctly positioned. Complete the installation.
6.6.3 Connecting the Battery connectors
Step 1 Remove the dust and waterproof cover of the BMS connector on the inverter and retain it.

Step 2 Connect the assembled DC connectors to the inverter.

Complete the installation.

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6.7 Ai-Dongle connection
Procedure: Step 1 Rotate the nut, take out the sealing ring, hold the locking structure, and take out the wiring terminal.

Step 2 Lock the communication cable to the wiring terminal according to the sequence shown in the following figure.

Step 3 Insert the wiring terminal into the sealing head, adjust the communication cable, insert the sealing ring, and lock nut.

Step 4 Remove the dust and waterproof cover of the Ai-Dongle on the inverter and retain it.

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Step 5 Attach the Ai-Dongle to the connection port in place and tighten it into the port by hand with the nut in the modular. Make sure the modular is securely connected and the label on the modular can be seen.

NOTICE
Rotating the communication modular will damage the communication modular! The communication modular is protected by locking nuts to protect the reliability of the connection. If the body of the communication modular is rotated, the communication modular will be damaged. It can only be locked by a nut. Do not rotate the communication modular body.
Complete the installation.

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6.8 Communication equipment connection
6.8.1 Communication interface description
The inverter is equipped with a communication interface, which is used to connect communication cables such as lithium battery, electricity meter and parallel inverter. The interface configuration of the communication interface is shown in the following figure.

PIN definition

Object

Description Terminal

TCP/IP

RJ-45

TX+

TX- RX+ X

RX-

BMS

RJ-45

GND X CANAH CANAL X

Monitor

RJ-45 RS485A RS485B GND X

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Object A B
C D E*1

Description DO2/DO1

DI*4/DRM0 CT
RS485

Terminal 4pin

Multifunction Relay

PIN definition

Multifunction Relay

Smart Meter

6pin

RS485A RS485B Ripple Control Receiver Device

6pin

DI_4

DI_3

DI_2

DI_1

Current Transformer L1 Current Transformer L2 6pin

Red

Black

Red

Black

4pin RS485A RS485B

GND

NS-protection (network and system
protection) Device

Positive Negative

DRMS Device

REF GEN/0

COM LOAD/0
or GND

Current Transformer L3

Red

Black

F*1

RS485

4pin RS485A RS485B

GND

*1 If E and F are connected to an inverter that supports only the parallel RJ45 interface, the RJ45 interface Pin1 is RS485A and Pin2 is RS485B

Com port Description

Function

USB

USB port

RS485 port

Monitor device

The firmware can be storage in the USB disk. The product will update automatically after the USB disk insert to USB interface.
The RS485 interfaces used to the product parallel operation.
The PIN1PIN2 of RS485 interface used to connect the product to the thirdparty monitor device. If you don’t want to use Ai-Dongle, the third party monitor device can be used.

BMS communication port

The RS-485/CAN interface used to connect the BMS (Battery Manage System) of the battery. If the communication interface of the BMS is CAN interface, the pins for CAN interface can be chosen to connect.

Multifunction Relay

The product comes standard with two multifunctional relays that can withstand up to 250V/1A. Multifunctional relays can be configured to operate in specific systems such as heat pump signal. For more information, please contact AISWEI Services.

Smart Meter

Terminal 2 can be used to connect the smart meter and NS-protection

NS-protection (network and (network and system protection) device. The PIN definition is shown as above

system protection) Device

table.

Terminal 3 can be used to connect the ripple control receiver and DRMs

Ripple control receiver device device. The PIN definition is shown as above table. Especially the PIN 6 (GND)

DRMs device

is a common port for both devices. For DRM0 application, please connect

PIN5 (REF GEN) and PIN6(COM LOAD).

Current transformer

Terminal 4 can be used to connect three current transformers. The PIN definition is shown as above table.

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The NS protection control signal requires 10-24V voltage.
6.8.2 Communication cable connection
Step 1 Remove the communication cover.
Step 2 Route the communication cable through the communication cover and crimp the wiring terminal. The sequence of the crimping wires of the wiring terminals is shown in the following figure:

Step 3 Connect the communication cable crimped to the corresponding communication port.

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Step 4 Install the communication cover on the inverter.

Step 5 Tighten the cable gland nuts.

Complete the installation.
6.8.3 Ripple control receiver connection
The product is equipped with one interface (terminal block C) to connect a Ripple Control Receiver device. The Ripple control receiver device can be connected to terminal block C(pin1~pin4pin6).

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Step 1Remove the cable jacket and strip the wire insulation.
Step 2Remove the push-in connector from the accessory pack. Insert the stripped wires into the push-in terminal connector. Step 3Insert the push-in connector into the connection panel and ensure the connection is secure.
Step 4Strip the insulation of the other end of the cable and terminate the wire into the terminal of the ripple control receiver according to the ripple control receiver requirements. Refer to the user manual of the ripple control receiver for further information.

Installation completed. 62

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6.8.4 NS protection connection
The product is equipped with one connection (terminal block B) for connection to an external central grid protection device.

Step 1Remove the cable jacket and strip the wire insulation.
Step 2Remove the push-in connector from the accessory pack. Insert the stripped wires into the push-in terminal terminals. Step 3Insert the push-in connector into the connection panel and ensure the connection is secure.
Step 4Strip the insulation of the other end of the cable and terminate the wire into the terminal according to external protection device requirements. Refer to the user manual of the external protection device for further information.

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Installation completed.
The Figure above is as reference and the manual of the third party device should be consulted, as also the manuals of other brands.

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6.8.5 Current Transformer connection
CT is an optional accessory.

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6.8.6 Smart meter connection (Eastron SDM630-Modbus V2)
The grid structure supported by the product is TN-S. For other grid types, please refer to 4.4.
EASTRON Meter

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6.8.7 Smart meter connection (CHINT DTSU666)

NOTICE
Only Eastron and CHINT meters are supported. Meter in the attachment bag is CHINT DTSU666 . Models that support EASTRON meters are EASTRON SDM630-Modbus V2 and EASTRON SDM630MCT V2 . Only meters provided by Soplanet can be used.

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7 Commissioning and operating
7.1 Inspection before commissioning CAUTION
Danger to life due to high voltages on DC conductors! When exposed to sunlight, the PV array generates dangerous DC voltage which is present in the DC conductors. Touching the DC and AC conductors can lead to lethal electric shocks.. Only touch the insulation of the DC cables. Only touch the insulation of the AC cables. Do not touch ungrounded PV modules and brackets. Wear personal protective equipment, such as insulating gloves.
Check the following items before starting the inverter: Make sure the inverter DC switch and external circuit breaker are disconnected. Make sure the inverter has been correctly mounted with wall bracket. Make sure nothing is left on the top of the inverter. Make sure the communication cable and AC connector have been correctly wired and tightened. Make sure the inverter’s exposed metal surface has a ground connection. Make sure the DC voltage of the strings does not exceed the permitted limits of the inverter. Make sure the DC voltage has the correct polarity. Make sure that the insulation resistance to ground is greater than the insulation resistance pro- tection value. Make sure the grid voltage at the point of connection of the inverter complies with the permitted value of the inverter. Make sure the AC circuit breaker complies with this manual and all applicable local standards. Make sure The phase sequence of the grid-side wiring of all parallel inverters is completely consistent. If EPS is parallel ,
the EPS phase sequence also must be completely consistent.
7.2 Commissioning procedure
If all of the items mentioned above meet the requirements, proceed as follows to start up the inverter for the first time.
Step 1 Turn the DC switch of the inverter to “ON” position and start battery, but keep the breakers on EPS and grid port to “OFF” position.
Step 2 Connect the inverter with soplanet APP, For details, please refer to 8.4. Then set grid code, operation mode(refer to 4.7), merter or CT type, battery model and SOC limit refer to 8.4.
Step 3 Turn the breakers on EPS and grid port to “ON” position. If the irradiation and grid conditions meet requirements, the inverter will operate normally.
Step 4 Observe the LED indicator to ensure inverter operates normally, check the inverter and battery parameters in APP.

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8 Solplanet APP
8.1 Brief introduction
The Solplanet App can establish communication connection to the inverter via the WLAN, there by achieving near-end maintenance on the inverter. Users can view inverter information and set parameters through the App.
8.2 Download and install
Scan the following QR code to download and install the App according to the prompt information.

Android

iOS

8.3 Create an account
If you do not have an account, you need to register a new account first. Procedure:
Step 1 Open Solplanet App to enter the login screen, and tap “Do not have an account” to enter the next screen. Step 2 The user groups “Business user” and “End user” need be selected according to your identity, and tap “Next step”.

The end user and the business user have the different permissions for setting parameters. The end user only can set the parameter during commissioning. The business user has more permissions, but they need submit more identity authentication documents.
Step 3 Enter the right mobile phone number (Via SMS) or E-mail address (Via mail). And tap the “Send verification code”
Step 4 Enter the correct verification code to automatically enter the next page.
Step 5 Set the password and click “Register” to complete the registration.

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8.4 Create a plant
Procedure: Step 1 Open Solplanet App to enter the login screen, enter the account name and password, and tap “Log in” to enter the next screen. Step 2 Tap the symbol “+” to enter the next screen, and tap “Create or modify a plant”, then the camera of the mobile automatically turns on, and scan the QR code of the Ai-dongle to enter the next screen, tap “Create new plant” to the next screen. Step 3 Enter the PV plant information in all fields marked with a red asterix, and tap “Create” to enter the next screen. Step 4 After the planet created, tap “Add dongle to the plant”, and tap “Add to plant” to the next screen. Step 5 Tap the inverter serial number that matches your inverter, then the setting parameter can be set. The detail description can be found at section 8.5.
The grid code should be chosen at this step. And the parameters also should be set if the grid company has the different requirements. Step 6The Energy Management shall be set here. Tap “Energy storage settings” to the next page, then tap “Battery settings” to select the battery model, battery number and choose the energy management model. After the parameter configuration, tap “Confirm” and tap the left arrow to go back the inverter list page. Then tap “Next step” to enter the next page.
The battery discharge minimum is valid only in grid-connected mode, and the off-grid default is 10%. Step 7 The parameter of the “Export Power Control” can be set, and tap “Save” after the parameter configuration. Then tap “Nest step” to enter the next page. Step 8 Tap “Continue”, and choose WiFi network from the list, and enter WiFi network password. Then tap “continue” to enter the next step. Step 9 Observe whether the Led blue light of the dongle stays on. If it is always on, it means that the network configuration is successful, and you can tap “Complete” to complete the configuration. Otherwise, you need to go back to the previous step and re-enter the Wi-Fi password. Step 10 Now the new plant have been created. Tap the plant to review the information of the plant.

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Eastron SDM630-Modbus V2

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Eastron SDM630-Modbus V2

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8.5 Setting parameters
8.5.1 Inverter configuration
The Solplanet’s products comply with local grid code when leaving the factory. But you still should check the grid code and the parameters according to the requirements of the installation site. Once configuration of the product is completed, the product will start operating automatically

Table description

No.

Function

Inverter Details

Function settings

Grid code settings

Active power settings

Description
Show the general information of the inverter. Show the present operation value of the inverter.
Active the general function. Active some special function.
Choose a safety code. Configure the protection parameters. Configure the start operation parameters and automatic reconnection parameters.
Configure the parameters of the P(U) curve. Configure the parameters of the P(f) curve. Configure the parameters of the active power limited. Configure the parameters of the active power increasing and decreasing speed.

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Reactive power settings

Choose the reactive power control mode. Configure the
parameters of the Q (U) curve. Configure the parameters of the cos (P) curve. Configure the parameters of the fix Q value or fix cos value.

Inverter update

Update the firmware of the inverter and monitor device. Update the safety package.

Configure the parameters of the LVRT. Dynamic network support setting

Configure the parameters of the HVRT.

Power on/off

Remote turn on/off the inverter on the App.

Energy storage settings

Configure the parameters of the Hybrid inverter. Configure the parameters of the battery. Configure the parameters of the generator.

Modbus address modification Modify the modbus communication address.

8.5.2 Grid code settings

For the Australia market, the inverter cannot be connected to the grid before the safety related area is set. Please select from Australia Region A/B/C to comply with AS/NZS 4777.2:2020, and contact your local electricity grid operator on which Region to select.
Normally you only need choose the grid code from the support grid code list. The product has fully complied with the standards that are added in the list. If the local grid operator has the other requirement, you can can set the parameter according to the requirement after you get the approval. Procedure:
Step 1 Tap “Grid code setting” to enter to the next page.
Step 2 Swipe the smartphone screen to choose the right grid code, then tap “Save” and go back the previous page.

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8.5.3 Active power reduction at overfrequency P(f)
There are four modes (Please refer to the following table) can be chosen for this function and many parameters can be configured according to the requirement of the local grid company. Procedure:
Step 1 Tap “Active power settings” to enter to the next page. Step 2 Tap “Overfrequency response settings” to enter to the next page. Step 3 Tap the drop-down menu to choose the mode of this function. Step 4 Configure the parameters and tap “Save”.

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Table description

No.

Name

Act. Power as a

percentage of Pn,

Linear

Act. Power as a

percentage of Pn,

hysteresis

Act. Power as a

percentage of

PM, Linear

Act. Power as a

percentage of

PM, hysteresis

Threshold

frequency f1

Deactivation

threshold fstop

Reset frequency

freset

Droop P

Intentional

delay time

Deactivation

time tstop

Active power

gradient

Description
Droop is defined as the active power as a percentage of Pn. The active power will continuously move up and down the frequency characteristic curve in the frequency range of f1 to fstop. Droop is defined as the active power as a percentage of Pn. The active power shall remain at or below the lowest power output level reached in response to the increase in frequency between f1 to fstop. Droop is defined as the active power as a percentage of PM. The active power will continuously move up and down the frequency characteristic curve in the frequency range of f1 to fstop. Droop is defined as the active power as a percentage of PM. The active power shall remain at or below the lowest power output level reached in response to the increase in frequency between f1 to fstop.
The threshold frequency for activating active power response to overfrequency. The threshold frequency for deactivating the active power response to overfrequency or disconnecting the inverter from the grid. The threshold frequency for deactivating the active power response to overfrequency after the frequency reducing. Reducing the active power in percentage of Pn or PM when the frequency rise to fstop. The delay time for activating active power response to overfrequency after the frequency over f1. An intentional delay shall be programmable to adjust the dead time to a value between the intrinsic dead time and 2s. The delay time that the active power can increase after the frequency below freset.
The active power increasing gradient as a percent of Pn per minutes after the frequency reducing to freset.
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Here, the Droop is different from the Droop S in section 3.7.2 of the standard EN 50549-1. If you want to configure the Droop S, the formula as below should be used to configure.
8.5.4 Active power reduction at overvoltage P(U)
There are five modes (Please refer to the following table) can be chosen for this function and many parameters can be configured according to the requirement of the local grid company. Procedure:
Step 1 Tap “Active power settings” to enter to the next page. Step 2 Tap “Overvoltage response settings” to enter to the next page. Step 3 Tap the drop-down menu to choose the mode of this function. Step 4 Configure the parameters and tap “Save”.

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Table description

No.

Name

Act. Power as a

percentage of

PM, Linear

Act. Power as a

percentage of

PM, hysteresis

Description
Droop is defined as the active power as a percentage of PM. The active power will continuously move up and down the voltage characteristic curve in the voltage range of Ustart to Ustop. The active power reduce from the PM that is the instantaneous active power at the time of exceeding Start voltage Ustart.
Droop is defined as the active power as a percentage of PM. The active power shall remain at or below the lowest

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Act. Power as a

percentage of PN,

Linear

Act. Power as a

percentage of

PN, hysteresis

Act. Power control for Taiwan

Start voltage

Ustart

Stop voltage

Ustop

Reset voltage

Ureset

Droop P

Intentional

delay time

11 12
86

Deactivation time tstop
Active power gradient

power output level reached in response to the increase in voltage between Ustart to Ustop. The active power reduce from the PM that is the instantaneous active power at the time of exceeding Start voltage Ustart.
Droop is defined as the active power as a percentage of PN. The active power will continuously move up and down the voltage characteristic curve in the voltage range of Ustart to Ustop. The active power reduce from the rated active power Pn at all time. The active power maybe don’t reduce if the limited value of the curve is lower than the instantaneous active power at the time of exceeding Start voltage Ustart.
Droop is defined as the active power as a percentage of PN. The active power shall remain at or below the lowest power output level reached in response to the increase in the voltage range of Ustart to Ustop. The active power reduce from the rated active power Pn at all time. The active power maybe don’t reduce if the limited value of the curve is lower than the instantaneous active power at the time of exceeding Start voltage Ustart.
Special control mode for Chinese Taiwan market.
The threshold voltage for activating active power response to overvoltage.
The threshold voltage for deactivating the active power response to overvoltage or disconnecting the inverter from the grid.
The threshold voltage for deactivating the active power response to overvoltage after the voltage reducing. Reset voltage does not work in the mode “Act. Power as a percentage of PN, Linear”.
Reducing the active power in percentage of PN or PM when the voltage rise to Ustop.
The delay time for activating active power response to overvoltage after the voltage over Ustart. An intentional delay shall be programmable to adjust the dead time to a value between the intrinsic dead time and 2s.
The delay time that the active power can increase after the voltage below Ureset.
The active power increasing gradient as a percent of Pn per minutes after the frequency reducing to freset.
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8.5.5 Cos(P) curve configuration
The power related control mode cos(P) controls the cos of the output as a function of the active power output. There are four coordinate points that can be configured. The coordinate points are the active power as a percentage of Pn and the displacement factor cos. Procedure:
Step 1 Tap “Reactive power settings” to enter to the next page.
Step 2 Tap “Enable reactive power” to choose the reactive power control mode and tap the left arrow to go back.
Step 3 Tap “Cos(P) curve settings” to enter to the next page. Step 4 Configure the parameters and tap “Save”.

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Table description

No.

Parameter

P/Pn

Cos

Phase

Description The active power as a percentage of PN. The displacement factor that is cosine of the phase angle between the fundamental components of the line to neutral point voltage and the respective current. Choose the over-excited or under-excited.
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Activating

voltage

Deactivating

voltage

The lock-in voltage value that enables the automatic reactive power delivery mode. Activation threshold as a percentage of Un corresponds to `lock-in’ voltage.
The lock-out voltage value that disables the automatic reactive power delivery mode. Deactivation threshold as a percentage of Un corresponds to `lock-out’ voltage

Some grid companies maybe requires two voltage thresholds as a percentage of Un to activate or deactivate the function. The voltage thresholds normally call `lock-in’ and `lock-out’ voltage.
8.5.6 Q(U) curve configuration
The voltage related control mode Q(U) controls the reactive power output as a function of the voltage. There are four coordinate points that can be configured. The coordinate points are the voltage as a percentage of Un and the reactive power as a percentage of Pn. Procedure:
Step 1 Tap “Reactive power settings” to enter to the next page. Step 2 Tap “Enable reactive power” to choose the reactive power control mode and tap the left arrow to go back. Step 3 Tap “Q(U) curve settings” to enter to the next page. Step 4 Configure the parameters and tap “Save”.

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Table description

No.

Name

U/Un

Q/Pn

Phase

Activating power

as a percentage

of Pn

Deactivating

power as a

percentage of Pn

Description
The voltage as a percentage of UN.
The reactive power as a percentage of Pn.
Choose the over-excited or under-excited.
The lock-in active power value that enables the automatic reactive power delivery mode. Activation threshold as a percentage of Pn corresponds to `lock-in’ power. The lock-out active power value that disables the automatic reactive power delivery mode. Deactivation threshold as a percentage of Pn corresponds to `lock-out’ power.

Some grid companies maybe requires two active power thresholds as a percentage of Pn to activate or deactivate the function. The active power thresholds normally call `lock-in’ and `lock-out’ active power.

8.6 Parallel parameter setting and using
The product is shipped based to the single inverter configuration. Parallel application requires reset the parameters. After the parallel system assembly is completed, the steps for setting parameters are as follows:

Step 1 Refer to Chapters 8.1-8.5 to download and install the APP, configure the power station, and connect to the Internet.

Step 2 Tap “Create or modify a plant”, then the camera of the mobile automatically turns on, and scan the QR code of the Ai-dongle to enter the next screen, tap “Create new plant” to the next screen.

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Step 3 Tap “Scan inverter”, the serial numbers of all inverters in the parallel system will be scanned out, and the APP will automatically set the inverter with stick as the master inverter, and the other inverters as slave inverter. If any are missing, confirm the wiring and scan again. If the EPS side in parallel, the Multi machine EPS in parallel in APP must be turned on after scan out, it can be setup only in off state.
Step 4 Tap “Configure parameters”, then the camera of the mobile automatically turns on, and scan the QR code of the Ai-dongle to enter the next screen, choose the inveter setting parameters.
Power on the PV of all parallel inverters, but do not power on the battery and AC. When the parallel wiring is completed, the battery and AC power cannot be connected before the parallel parameters
are setup. Unless remote shutdown is set for each inverter through the APP, the master inverter can be turned on again after setting up the parallel system.
For parallel system, all inverters are setup through the master inverter page. After setting the master inverter parameters, all slaver inverters will set this parameter. For example, if master inverter set the output power to 1KW in a system with four inverters, the output power of the entire system is 1KW*4. When Multi machine EPS in parallel is enable, the total EPS current and power only display in master inverter. The battery information can be read in their own list.

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Multi machine EPS in parallel
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Multi machine EPS in parallel
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8.7 Asymmetrical power output
If user enable Asymmetrical power output, the inverter will asynchronous output. Which means that in self-consumption mode with unbalance three phase load, the inverter correspondingly output three-phase imbalance unless load power is too high (above 1/3 rate power) to consume grid power.

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Before enable Asymmetrical power output, make sure the phase sequence of CT or meter is consistent with grid and inverter.otherwise inverter will work abnormal.
If Asymmetrical power output is enable, the export power control can chose Lower phase power. in this mode , every phase(L1,L2,L3) will not export power to grid even if there is a value in export power limit setpoint.

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8.8 Digital output and Heat pump settings
In the Digital output menu, you can configure the two Digital output interfaces (DO1/DO2). The Heat pump control parameters can be configured in the Heat pump settings. The two items are associated, and you should start with the Digital output interfaces before the Heat pump settings.
Procedure:
Step 1 Refer to “8.4 Create a plant” to enter the “Inverter Configuration” screen.
Step 2 Tap “Function Setting” to enter the next screen , and tap “Digital output” to enter the next screen.
Step 3 Configuring the DO1/DO2 : The DO1 and DO2 can be configured on the Digital output page. Each DO can be configured as ” Not Used “, ” PV Ready Heat Pump “, ” SG Ready Pump “. The user can select the appropriate option according to the needs. Tap “Save” when the configuration is complete, Then a Tip window will pop up, tap “Exit” to exit, tap “Yes” will jump to the Heat pump settings page.
Step 4 Heat pump Settings tap “Yes” in the previous step to enter the Heat pump Settings page, You can also directly tap Heat pump Settings to enter the Heat pump Settings page On this page, you can set the control parameters of the heat pump. Tap “Save” when the Settings are complete . Refer to the following table description for the meanings of the Settings.

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No.
1 8
2 3 4

Function

Description

Threshold based on Threshold power

The inverter can control the operation mode of a compatible heat pump according to the defined threshold . There are two options in the drop-down menu: Total PV generation and Export to grid. The first uses the AC output power of the inverter as the basis for the threshold whereas the second uses the AC power output to the grid using data from the main meter. Note that the battery is prioritized higher than the heat pump.
The power threshold that regulates the operating state of the compatible heat pump. When the defined power level is fulfilled throughout the defined “Min. time needed” the DO state is changed to signal the heat pump to start if possible. Likewise, once the defined power level is no longer fulfilled throughout the “Min. time needed” the DO state is changed to signal the heat pump to stop if possible.
Note that the Hold-time is also respected.

The Min. time needed defines for how long the defined power level must be Min. time needed (Power states)
available or unavailable to switch the DO state(s).

Hold-time (DO states)

The Hold-time defines for how long a relay state must be kept as a minimum after a change.

Heat pump status display

The display of the working state of the heat pump. There are two working states, one is Normal operation (Mode 2) and the other is Encouraged operation (Mode 3).

DO state

Validation test

The DO states show if they are open or closed.
The validation test function can be used to for 10 minutes temporarily set the DOs to trigger the heat pump to start, if possible. This can be used if conditions are not currently fulfilled to trigger the heat pump. This is useful to validate the wiring and settings in the heat pump itself.
The validation test can be manually stopped and otherwise it will automatically cease and return to normal logic after 10 minutes.

8.9 Activated Arc-fault Circuit Interrupter (AFCI)
The Solplanet App can establish a communication connection to the inverter via WLAN, thereby achieving near-end maintenance on the inverter. The Arc-fault Circuit Interrupter (AFCI) function can be activated on the Solplanet App. Both the “Business user” and “End user” user groups can activate the AFCI function during PV plant commissioning. However, only the “Business user” can activate the AFCI function after the PV plant is operating normally. Procedure:
Step 1 Refer to “8.4 Create a plant” to enter the “Inverter Configuration” screen.
Step 2 Tap “Function Settings” to enter the next screen, and tap “AFCI” to enter the next screen.
Step 3 Tap the switch “Enable AFCI”, then the automatic self-test function will be performed.
Step 4 The “Alarm detection sensitivity” and “Reconnection method” can be chosen. If “Low sensitivity” is chosen, the inverter will automatically analyze and determine whether the current fault is a genuine arc fault, and the error code will be sent only for genuine arc faults. If “Normal sensitivity” is chosen, the error code will be sent immediately.

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When the AFCI function is enabled for the first time, a self-test will be performed automatically before operation. Additionally, the self-test will be performed once every 24 hours after the initial operation. If manual reconnection is chosen, the inverter will not restart after detecting an arc until the fault is cleared manually. If automatic reconnection is chosen, the inverter will restart with a minimum delay time of 5 minutes after detecting an arc. When interrupting the fifth time within a 24 h period, the inverter is only allowed to be reset manually.

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9 Decommissioning the product

9.1 Disconnecting the inverter from voltage sources
Prior to performing any work on the product, always disconnect it from all voltage sources as described in this section. Always adhere to the prescribed sequence.
WARNING
Danger to life due to electric shock from destruction of the measuring device due to overvoltage Overvoltage can damage a measuring device and result in voltage being present in the enclo- sure of the measuring device. Touching the live enclosure of the measuring device results in death or lethal injuries due to electric shock. Only use measuring devices with a DC input voltage range of 1100 V or higher.

Procedure: Step 1 Disconnect the miniature circuit breaker and secure against reconnection.

Step 2 Disconnect the DC switch and secure against reconnection.

Step 3 Wait until the LEDs have gone out.

Step 4 Use a current clamp meter to ensure that no current is present in the DC cables.
DANGER

Danger to life due to electric shock when touching exposed DC conductors or DC plug contacts if the DC connectors are damaged or loose
The DC connectors can break or become damaged, become free of the DC cables, or no longer be connected correctly if the DC connectors are released and disconnected incorrectly. This can result in the DC conductors or DC plug contacts being exposed. Touching live DC conductors or DC plug connectors will result in death or serious injury due to electric shock.
Wear insulated gloves and use insulated tools when working on the DC connectors. Ensure that the DC connectors are in perfect condition and that none of the DC conductors or DC plug contacts are exposed. Carefully release and remove the DC connectors as described in the following.

Step 5 Loosen and remove the DC connector.

Type 1 DC connector

Type 2 DC connector

Release and remove the DC connectors. To do so, insert a flatblade screwdriver or an angled screwdriver (blade width: 3.5mm) into one of the side slots and pull the DC connectors out.

To remove DC plug connectors, insert a wrench tool into the slots and press the wrench tool with an appropriate force.

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Step 6 Ensure that no voltage is present between the positive terminal and negative terminal at the DC inputs using a suitable measuring device.

Step 7 Loosen and remove the Grid connector.

Rotate the latch as shown.

Unlock instructions
Remove the female end of the cable to unlock the account.

Step 8 Loosen and remove the EPS Load connector.

Rotate the latch as shown.

Unlock instructions
Remove the female end of the cable to unlock the account.

Step 9 Loosen and remove the Battery connector.

Unlock instructions

Insert a flat-blade screwdriveror an angled screwdriver (blade width: 3.5mm) into one of the side slots.

Pull the DC connectors out.

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Step 10 Remove the communication cover. Remove the communication cable in reverse order by referring to 6.7 Communication equipment connection. Step 11 Hold down the buckle on the side of the Ai-Dongle and pull out the Ai-Dongle terminal.
9.2 Dismantling the inverter
After disconnecting all electrical connections as described in Section 9.1, the inverter can be removed as follows Procedure:
Step 1 Dismantle the inverter referring to “5.3 Mounting” in reverse steps. Step 2 If necessary, remove the wall-mounting bracket from the wall. Step 3 If the inverter will be reinstalled in the future, please refer to “3.2 Inverter Storage” for a proper conservation.

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10 Technical data

10.1 ASW05kH/06kH/08kH/10kH/12kH-T2

10.1.1 For European market

Type

ASW05kH -T2 ASW06kH -T2 ASW08kH -T2 ASW10kH -T2

DC Input

Maximum power of PV array

7500 Wp

9000 Wp

12000 Wp

15000 Wp

Max. power per MPP tracker

7500 W

9000 W

10000 W

Maximum input voltage Rated input voltage Minimum input voltage Start voltage MPP voltage range
MPP voltage range at Pnom

150-950 V 250~850 V

150-950 V 290~850 V

1100 V 630 V 60 V 180 V 200-950 V
350-850 V

200-950 V 380-850 V

Max. input current

20 A/20 A

Isc PV (absolute maximum)

30 A/30 A

Maximum reverse current into the PV modules

0 A

Number of independent MPP inputs

Strings per MPP input
Overvoltage category in accordance with ICE 60664-1

PV1:1/PV2:1
II

AC Input and Output
Rated output power at 230 V Rated apparent power at cos = 1 Maximum apparent power at cos = 1

5000 W 5000 VA 5000 VA

6000 W 6000 VA 6000 VA

8000 W 8000 VA 8000 VA

10000 W 10000 VA 10000 VA

Rated grid voltage

220 V / 380 V [3/N/PE] 230 V / 400 V [3/N/PE] 240 V / 415 V [3/N/PE]

Grid voltage range

270-480 V (Phase to Phase)

Rated grid frequency

50 Hz/60 Hz

Grid frequency range

45-55 Hz/55-65 Hz

Rated output current at 220 V

7.6 A

9.1 A

12.2 A

15.2 A

Rated output current at 230 V

7.3 A

8.7 A

11.6 A

14.5 A

Rated output current at 240 V

7.0 A

8.4 A

11.2 A

13.9 A

Maximum output current

8.0 A

9.6 A

12.8 A

16.0 A

Max. input power from grid

10000 W

12000 W

16000 W

20000 W

Max. input current from grid

14.5 A

17.4 A

23.2 A

29.0 A

Inrush current

<20% of nominal AC current for a maximum of 10ms

8.0 A 8.0 A 20.0 A

9.6 A

60 A 12.8 A

16.0 A

9.6 A

12.8 A

16.0 A

25.0 A

32.0 A

<3% (of nominal power)

ASW12kH -T2 18000 Wp 10000 W
200-950 V 450-850 V
12000 W 12000 VA 12000 VA
18.2 A 17.4 A 16.7 A 19.2 A 24000 W 34.8 A
19.2 A 19.2 A 40.0 A

104

UM0077_ASW05-12kH-T2-T3(TCP version)_EN_V01_0425

the AC voltage <2%, and AC power >50% of the rated power
Adjustable displacement power factor Overvoltage category in accordance with IEC 60664-1
Efficiency
Maximum efficiency European weighted efficiency
Battery data
Max charging power Max discharging power
Battery voltage range
Max charging current
Max discharging current
Rated charging current
Rated discharging current
Battery type
EPS load data Rated apparent power at 400V Max. apparent power at 400V, continuous ongrid Max. apparent power at 400V continuous offgrid Max. apparent power at at 400V, off-grid <10s Max. power on each phase at 400V, continuous on-grid Max. power on each phase at 400V, continuous off-grid

98.0% 97.2% 5000 W 5000 W
5000 W 10000 VA 5000 VA 10000 VA 3333 W
1667 W

Nominal output voltage

AC grid frequency Max. continuous output current Max. output current < 10s Rated current at 400V Max. current at 400V, continuous on-grid Max. current at 400V, continuous off-grid Total harmonic distortion (THDv, linear load) Switching time to battery-backup operation

8.0 A 14.5 A 7.3 A 14.6 A 7.3 A

0.8 leading to 0.8 lagging III

98.2% 97.5%

98.4% 97.9%

6000 W 6000 W

8000 W 8000 W 120~600 V
30 A 30 A 30 A 30 A LiFePO4

10000 W 10000 W

6000 W 12000 VA

8000 W 16000 VA

10000 W 20000 VA

6000 VA 12000 VA 4000 W

8000 VA 16000 VA 5333 W

10000 VA 20000 VA
6667 W

2000 W

2667 W

3333 W

9.6 A 17.4 A 8.7 A 17.4 A 8.7 A

220 V / 380 V [3/N/PE] 230 V / 400 V [3/N/PE] 240 V / 415 V [3/N/PE] 50 Hz / 60 Hz 12.8 A 23.2 A 11.6 A 23.2 A 11.6 A 2% <10 ms

16.0 A 29.0 A 14.5 A 29.0 A 14.5 A

(1) The voltage range meets the requirements of the corresponding national grid code. (2) The frequency range meets the requirements of the corresponding national grid code.

10.1.2 For Australian market

Type DC Input Maximum power of PV array Max. power per MPP tracker Maximum input voltage

ASW05kH -T2
7500 Wp 7500 W 1100 V

UM0077_ASW05-12kH-T2-T3(TCP version)_EN_V01_0425

98.4% 97.9% 12000 W 12000 W
12000 W 24000 VA 12000 VA 24000 VA 8000 W 4000 W
19.2 A 34.8 A 17.4 A 34.8 A 17.4 A
105

Rated input voltage Minimum input voltage Start voltage MPP voltage range MPP voltage range at Pnom Max. input current Isc PV (absolute maximum)
Maximum reverse current into the PV modules Number of independent MPP inputs
Strings per MPP input Overvoltage category in accordance with ICE 60664-1 AC Input and Output Rated output power at 230 V Rated apparent power at cos = 1 Maximum apparent power at cos = 1
Rated grid voltage
Grid voltage range Rated grid frequency Grid frequency range Rated output current at 220 V Rated output current at 230 V Rated output current at 240 V Maximum output current Max. input power from grid Max. input current from grid Inrush current Contribution to peak short-circuit current ip Initial short-circuit alternating current (Ik” first single period effective value) Short circuit current continuous [ms] (max output fault current) Recommended rated current of AC circuit Breaker Total harmonic distortion of the output current with total harmonic distortion of the AC voltage <2%, and AC power >50% of the rated power Adjustable displacement power factor Overvoltage category in accordance with IEC 60664-1 Efficiency Maximum efficiency European weighted efficiency
Battery data Max charging power Max discharging power Battery voltage range
106

630 V 60 V 180 V 150-950 V 250~850 V 20 A/20 A 30 A/30 A 0 A
2 PV1:1/PV2:1
II
5000 W 5000 VA 5000 VA 220 V / 380 V [3/N/PE] 230 V / 400 V [3/N/PE] 240 V / 415 V [3/N/PE] 270-480 V (Phase to Phase) 50 Hz/60 Hz 45-55 Hz/55-65 Hz
7.6 A 7.3 A 7.0 A 8.0 A 10000 W 14.5 A <20% of nominal AC current for a maximum of 10ms 60 A 8.0 A
8.0 A
20.0 A
<3% (of nominal power)
0.8 leading to 0.8 lagging III
98.0% 97.2%
5000 W 5000 W 120~600 V
UM0077_ASW05-12kH-T2-T3(TCP version)_EN_V01_0425

Max charging current Max discharging current Rated charging current Rated discharging current Battery type EPS load data Rated apparent power at 400V Max. apparent power at 400V, continuous ongrid Max. apparent power at 400V continuous offgrid Max. apparent power at 400V, off-grid <10s Max. power on each phase at 400V, continuous on-grid Max. power on each phase at 400V, continuous off-grid
Nominal output voltage
AC grid frequency Max. continuous output current Max. output current < 10s Rated current at 400V Max. current at 400V, continuous on-grid Max. current at 400V, continuous off-grid
Total harmonic distortion (THDv, linear load) Switching time to battery-backup operation

30 A 30 A 30 A 30 A LiFePO4
5000 W 10000 VA
5000 VA 10000 VA 3333 W
1667 W 220 V / 380 V [3/N/PE] 230 V / 400 V [3/N/PE] 240 V / 415 V [3/N/PE] 50 Hz / 60 Hz 8.0 A 14.5 A 7.3 A 14.6 A 7.3 A 2% <10 ms

(1) The voltage range meets the requirements of the corresponding national grid code. (2) The frequency range meets the requirements of the corresponding national grid code.

10.2 ASW05kH/06kH/08kH/10kH/12kH-T2-O

10.2.1 For European market

Type

ASW05kH -T2- ASW06kH -T2- ASW08kH -T2- ASW10kH -T2- ASW12kH -T2-

DC Input

Maximum power of PV array

7500 Wp

9000 Wp

12000 Wp

15000 Wp

18000 Wp

Max. power per MPP tracker

7500 W

9000 W

10000 W

Maximum input voltage Rated input voltage Minimum input voltage Start voltage MPP voltage range
MPP voltage range at Pnom

150-950 V 250~850 V

150-950 V 290~850 V

1100 V 630 V 60 V 180 V 200-950 V
350-850 V

200-950 V 380-850 V

200-950 V 450-850 V

Max. input current

20 A/20 A

Isc PV (absolute maximum)

30 A/30 A

Maximum reverse current into the PV modules

0 A

UM0077_ASW05-12kH-T2-T3(TCP version)_EN_V01_0425

107

Number of independent MPP inputs
Strings per MPP input Overvoltage category in accordance with ICE 60664-1 AC Input and Output Rated output power at 230 V Rated apparent power at cos = 1 Maximum apparent power at cos = 1
Rated grid voltage

5000 W 5000 VA 5000 VA

Grid voltage range
Rated grid frequency
Grid frequency range
Rated output current at 220 V
Rated output current at 230 V
Rated output current at 240 V
Maximum output current
Max. input power from grid
Max. input current from grid
Inrush current
Contribution to peak short-circuit current ip Initial short-circuit alternating current (Ik” first single period effective value) Short circuit current continuous [ms] (max output fault current) Recommended rated current of AC circuit Breaker Total harmonic distortion of the output current with total harmonic distortion of the AC voltage <2%, and AC power >50% of the rated power Adjustable displacement power factor Overvoltage category in accordance with IEC 60664-1 Efficiency
Maximum efficiency European weighted efficiency
Battery data
Max charging power Max discharging power
Battery voltage range
Max charging current
Max discharging current
Rated charging current
Rated discharging current
Battery type

7.6 A 7.3 A 7.0 A 8.0 A 5000 W 8.0 A
8.0 A 8.0 A 16.0 A
98.0% 97.2% 5000 W 5000 W

2 PV1:1/PV2:1
II

6000 W 6000 VA 6000 VA

8000 W 8000 VA 8000 VA

10000 W 10000 VA 10000 VA

220 V / 380 V [3/N/PE] 230 V / 400 V [3/N/PE] 240 V / 415 V [3/N/PE]

270-480 V (Phase to Phase)

50Hz/60Hz

45-55Hz/55-65Hz

9.1 A

12.2 A

15.2 A

8.7 A

11.6 A

14.5 A

8.4 A

11.2 A

13.9 A

9.6 A

12.8 A

16.0 A

6000 W

8000 W

10000 W

9.6 A

12.8 A

16.0 A

<20% of nominal AC current for a maximum of 10ms

60 A

9.6 A

12.8 A

16.0 A

9.6 A

12.8 A

16.0 A

20.0 A

<3% (of nominal power)
0.8 leading to 0.8 lagging III

98.2% 97.5%
6000 W 6000 W

98.4% 97.9%

8000 W 8000 W 120~600 V
30 A 30 A 30 A 30 A LiFePO4

10000 W 10000 W

12000 W 12000 VA 12000 VA
18.2 A 17.4 A 16.7 A 19.2 A 12000 W 19.2 A
19.2 A 19.2 A 25.0 A
98.4% 97.9% 12000 W 12000 W

(1) The voltage range meets the requirements of the corresponding national grid code. (2) The frequency range meets the requirements of the corresponding national grid code.

108

UM0077_ASW05-12kH-T2-T3(TCP version)_EN_V01_0425

10.2.2 For Australian market
Type DC Input Maximum power of PV array
Max. power per MPP tracker
Maximum input voltage Rated input voltage Minimum input voltage Start voltage MPP voltage range MPP voltage range at Pnom
Max. input current
Isc PV (absolute maximum)
Maximum reverse current into the PV modules
Number of independent MPP inputs
Strings per MPP input Overvoltage category in accordance with ICE 60664-1 AC Input and Output Rated output power at 230 V Rated apparent power at cos = 1 Maximum apparent power at cos = 1
Rated grid voltage
Grid voltage range Rated grid frequency Grid frequency range Rated output current at 220 V Rated output current at 230 V Rated output current at 240 V Maximum output current Max. input power from grid Max. input current from grid Inrush current Contribution to peak short-circuit current ip Initial short-circuit alternating current (Ik” first single period effective value) Short circuit current continuous [ms] (max output fault current) Recommended rated current of AC circuit Breaker Total harmonic distortion of the output current with total harmonic distortion of the AC voltage <2%, and AC power >50% of the rated power Adjustable displacement power factor Overvoltage category in accordance with IEC 60664-1

ASW05kH -T2-O
7500 Wp 7500 W 1100 V 630 V
60 V 180 V 150-950 V 250~850 V 20 A/20 A 30 A/30 A 0 A
2 PV1:1/PV2:1
II
5000 W 5000 VA 5000 VA 220 V / 380 V [3/N/PE] 230 V / 400 V [3/N/PE] 240 V / 415 V [3/N/PE] 270-480 V (Phase to Phase) 50Hz/60Hz 45-55Hz/55-65Hz
7.6 A 7.3 A 7.0 A 8.0 A 5000 W 8.0 A <20% of nominal AC current for a maximum of 10ms 60 A 8.0 A
8.0 A
16.0 A
<3% (of nominal power)
0.8 leading to 0.8 lagging III

UM0077_ASW05-12kH-T2-T3(TCP version)_EN_V01_0425

109

98.0% 97.2%
5000 W 5000 W 120~600 V
30 A 30 A 30 A 30 A LiFePO4

(1) The voltage range meets the requirements of the corresponding national grid code. (2) The frequency range meets the requirements of the corresponding national grid code.

10.3 ASW08kH/10kH/12kH-T3
10.3.1 For European market

ASW08kH -T3 12000 Wp 10000 W
200-950 V 250-850 V
8000 W 8000 VA 8000 VA
12.2 A

ASW10kH -T3
15000 Wp 10000 W
1100 V 630 V 60 V 180 V 200-950 V 320-850 V 16 A/16 A/16 A 24 A/24 A/24 A
0 A 3
PV1:1/PV2:1/PV3:1
II
10000 W 10000 VA 10000 VA 220 V / 380 V [3/N/PE] 230 V / 400 V [3/N/PE] 240 V / 415 V [3/N/PE] 270-480 V (Phase to Phase) 50 Hz/60 Hz 45-55 Hz/55-65 Hz
15.2 A

ASW12kH -T3 18000 Wp 10000 W
200-950 V 380-850 V
12000 W 12000 VA 12000 VA
18.2 A

110

UM0077_ASW05-12kH-T2-T3(TCP version)_EN_V01_0425

Rated output current at 230 V
Rated output current at 240 V
Maximum output current
Max. input power from grid
Max. input current from grid
Inrush current
Contribution to peak short-circuit current ip Initial short-circuit alternating current (Ik” first single period effective value) Short circuit current continuous [ms] (max output fault current) Recommended rated current of AC circuit Breaker Total harmonic distortion of the output current with total harmonic distortion of the AC voltage <2%, and AC power >50% of the rated power Adjustable displacement power factor
Overvoltage category in accordance with IEC 60664-1
Efficiency
Maximum efficiency European weighted efficiency
Battery data
Max charging power Max discharging power
Battery voltage range
Max charging current
Max discharging current
Rated charging current
Rated discharging current
Battery type
EPS load data Rated apparent power at 400V Max. apparent power at 400V, continuous ongrid Max. apparent power at 400V continuous offgrid Max. apparent power at at 400V, off-grid <10s Max. power on each phase at 400V, continuous on-grid Max. power on each phase at 400V, continuous off-grid Nominal AC voltage
AC grid frequency
Max. continuous output current
Max. output current < 10s Rated current at 400V
Max. current at 400V, continuous on-grid

11.6 A

14.5 A

17.4 A

11.2 A

13.9 A

16.7 A

12.8 A

16.0 A

19.2 A

16000 W

20000 W

24000 W

23.2 A

29.0 A

34.8 A

<20% of nominal AC current for a maximum of 10ms

60 A

12.8 A

16.0 A

19.2 A

12.8 A

16.0 A

19.2 A

32.0 A

40.0 A

<3% (of nominal power) 0.8 leading to 0.8 lagging
III

98.4% 97.9% 8000 W 8000 W
8000 W 16000 VA 8000 VA 16000 VA 5333 W 2667 W
12.8 A 23.2 A 11.6 A 23.2 A

98.4% 97.9%
10000 W 10000 W 120~600 V
30 A 30 A 30 A 30 A LiFePO4
10000 W 20000 VA 10000 VA 20000 VA
6667 W 3333 W 230 V / 400 V [3/N/PE] 50 Hz / 60 Hz 16.0 A 29.0 A 14.5 A 29.0 A

98.4% 97.9% 12000 W 12000 W
12000 W 24000 VA 12000 VA 24000 VA 8000 W 4000 W
19.2 A 34.8 A 17.4 A 34.8 A

UM0077_ASW05-12kH-T2-T3(TCP version)_EN_V01_0425

111

Max. current at 400V, continuous off-grid Total harmonic distortion (THDv, linear load) Switching time to battery-backup operation

11.6 A

14.5 A 2%
<10 ms

(1) The voltage range meets the requirements of the corresponding national grid code. (2) The frequency range meets the requirements of the corresponding national grid code.

10.3.2 For Australian market

17.4 A

Type DC Input Maximum power of PV array Max. power per MPP tracker Maximum input voltage Rated input voltage Minimum input voltage Start voltage MPP voltage range MPP voltage range at Pnom Max. input current Isc PV (absolute maximum) Maximum reverse current into the PV modules Number of independent MPP inputs Strings per MPP input Overvoltage category in accordance with ICE 60664-1 AC Input and Output Rated output power at 230 V Rated apparent power at cos = 1 Maximum apparent power at cos = 1
Rated grid voltage
Grid voltage range Rated grid frequency Grid frequency range Rated output current at 220 V Rated output current at 230 V Rated output current at 240 V Maximum output current Max. input power from grid Max. input current from grid Inrush current Contribution to peak short-circuit current ip Initial short-circuit alternating current (Ik” first single period effective value) Short circuit current continuous [ms] (max output fault current) Recommended rated current of AC circuit Breaker
112

ASW08kH -T3

ASW10kH -T3

ASW12kH -T3

12000 Wp 10000 W
200-950 V 250-850 V

15000 Wp 10000 W
1100 V 630 V 60 V 180 V 200-950 V 320-850 V 16 A/16 A/16 A 24 A/24 A/24 A
0 A 3
PV1:1/PV2:1/PV3:1
II

18000 Wp 10000 W
200-950 V 380-850 V

8000 W 8000 VA 8000 VA

9999 W 9999 VA 9999 VA

12000 W 12000 VA 12000 VA

220 V / 380 V [3/N/PE] 230 V / 400 V [3/N/PE] 240 V / 415 V [3/N/PE]

270-480 V (Phase to Phase)

50 Hz/60 Hz

45-55 Hz/55-65 Hz

12.2 A

15.2 A

18.2 A

11.6 A

14.5 A

17.4 A

11.2 A

13.9 A

16.7 A

12.8 A

16.0 A

19.2 A

16000 W

20000 W

24000 W

23.2 A

29.0 A

34.8 A

<20% of nominal AC current for a maximum of 10ms

60 A

12.8 A

16.0 A

19.2 A

12.8 A

16.0 A

19.2 A

32.0 A

40.0 A

UM0077_ASW05-12kH-T2-T3(TCP version)_EN_V01_0425

Total harmonic distortion of the output current with total harmonic distortion of the AC voltage <2%, and AC power >50% of the rated power
Adjustable displacement power factor
Overvoltage category in accordance with IEC 60664-1

<3% (of nominal power) 0.8 leading to 0.8 lagging
III

Efficiency Maximum efficiency European weighted efficiency
Battery data Max charging power Max discharging power Battery voltage range Max charging current Max discharging current Rated charging current Rated discharging current Battery type
EPS load data Rated apparent power at 400V Max. apparent power at 400V, continuous ongrid Max. apparent power at 400V continuous offgrid Max. apparent power at at 400V, off-grid <10s Max. power on each phase at 400V, continuous on-grid Max. power on each phase at 400V, continuous off-grid Nominal AC voltage AC grid frequency
Max. continuous output current Max. output current < 10s Rated current at 400V Max. current at 400V, continuous on-grid
Max. current at 400V, continuous off-grid
Total harmonic distortion (THDv, linear load) Switching time to battery-backup operation

98.4% 97.9% 8000 W 8000 W
8000 W 16000 VA 8000 VA 16000 VA 5333 W 2667 W
12.8 A 23.2 A 11.6 A 23.2 A 11.6 A

98.4% 97.9%
10000 W 10000 W 120~600 V
30 A 30 A 30 A 30 A LiFePO4
9999 W 19998 VA 9999 VA 19998 VA 6666 W 3333 W 230 V / 400 V [3/N/PE] 50 Hz / 60 Hz
16.0 A 29.0 A 14.5 A 29.0 A 14.5 A
2% <10 ms

(1) The voltage range meets the requirements of the corresponding national grid code. (2) The frequency range meets the requirements of the corresponding national grid code.

10.4 ASW08kH/10kH/12kH-T3-O

10.4.1 For European market

Type DC Input

ASW08kH -T3-O

ASW10kH -T3-O

UM0077_ASW05-12kH-T2-T3(TCP version)_EN_V01_0425

98.4% 97.9% 12000 W 12000 W
12000 W 24000 VA 12000 VA 24000 VA 8000 W 4000 W
19.2 A 34.8 A 17.4 A 34.8 A 17.4 A
ASW12kH -T3-O 113

Maximum power of PV array
Max. power per MPP tracker
Maximum input voltage Rated input voltage Minimum input voltage Start voltage MPP voltage range MPP voltage range at Pnom
Max. input current
Isc PV (absolute maximum)
Maximum reverse current into the PV modules
Number of independent MPP inputs
Strings per MPP input Overvoltage category in accordance with ICE 60664-1 AC Input and Output Rated output power at 230 V Rated apparent power at cos = 1 Maximum apparent power at cos = 1
Rated grid voltage
Grid voltage range Rated grid frequency Grid frequency range Rated output current at 220 V Rated output current at 230 V Rated output current at 240 V Maximum output current Max. input power from grid Max. input current from grid Inrush current Contribution to peak short-circuit current ip Initial short-circuit alternating current (Ik” first single period effective value) Short circuit current continuous [ms] (max output fault current) Recommended rated current of AC circuit Breaker Total harmonic distortion of the output current with total harmonic distortion of the AC voltage <2%, and AC power >50% of the rated power Adjustable displacement power factor Overvoltage category in accordance with IEC 60664-1 Efficiency Maximum efficiency European weighted efficiency
Battery data
114

12000 Wp 10000 W
200-950 V 250-850 V

15000 Wp 10000 W
1100 V 630 V 60 V 180 V 200-950 V 320-850 V 16A/16A/16A 24A/24A/24A
0 A 3 PV1:1/PV2:1/PV3:1
II

18000 Wp 10000 W
200-950 V 380-850 V

8000 W 8000 VA 8000 VA

10000 W 10000 VA 10000 VA

12000 W 12000 VA 12000 VA

220 V / 380 V [3/N/PE] 230 V / 400 V [3/N/PE] 240 V / 415 V [3/N/PE]

270-480 V (Phase to Phase)

50Hz/60Hz

45-55Hz/55-65Hz

12.2 A

15.2 A

18.2 A

11.6 A

14.5 A

17.4 A

11.2 A

13.9 A

16.7 A

12.8 A

16.0 A

19.2 A

8000 W

10000 W

12000 W

12.8 A

16.0 A

19.2 A

<20% of nominal AC current for a maximum of 10ms

60 A

12.8 A

16.0 A

19.2 A

12.8 A

16.0 A

19.2 A

16.0 A

20.0 A

25.0 A

<3% (of nominal power)
0.8 leading to 0.8 lagging III

98.4% 97.9%

UM0077_ASW05-12kH-T2-T3(TCP version)_EN_V01_0425

Max charging power Max discharging power Battery voltage range Max charging current Max discharging current Rated charging current Rated discharging current Battery type

8000 W 8000 W

10000 W 10000 W 120~600 V
30 A 30 A 30 A 30 A LiFePO4

(1) The voltage range meets the requirements of the corresponding national grid code. (2) The frequency range meets the requirements of the corresponding national grid code.

10.4.2 For Australian market

12000 W 12000 W

ASW08kH -T3-O

ASW10kH -T3-O

ASW12kH -T3-O

12000 Wp 10000 W
200-950 V 250-850 V

15000 Wp 10000 W
1100 V 630 V 60 V 180 V 200-950 V 320-850 V 16A/16A/16A 24A/24A/24A
0 A 3 PV1:1/PV2:1/PV3:1
II

18000 Wp 10000 W
200-950 V 380-850 V

8000 W 8000 VA 8000 VA

9999 W 9999 VA 9999 VA

12000 W 12000 VA 12000 VA

220 V / 380 V [3/N/PE] 230 V / 400 V [3/N/PE] 240 V / 415 V [3/N/PE]

270-480 V (Phase to Phase)

50Hz/60Hz

45-55Hz/55-65Hz

12.2 A

15.2 A

18.2 A

11.6 A

14.5 A

17.4 A

11.2 A

13.9 A

16.7 A

12.8 A

16.0 A

19.2 A

8000 W

10000 W

12000 W

12.8 A

16.0 A

19.2 A

<20% of nominal AC current for a maximum of 10ms

UM0077_ASW05-12kH-T2-T3(TCP version)_EN_V01_0425

115

Contribution to peak short-circuit current ip Initial short-circuit alternating current (Ik” first single period effective value) Short circuit current continuous [ms] (max output fault current) Recommended rated current of AC circuit Breaker Total harmonic distortion of the output current with total harmonic distortion of the AC voltage <2%, and AC power >50% of the rated power
Adjustable displacement power factor Overvoltage category in accordance with IEC 60664-1
Efficiency
Maximum efficiency European weighted efficiency
Battery data
Max charging power Max discharging power
Battery voltage range
Max charging current
Max discharging current
Rated charging current
Rated discharging current
Battery type

12.8 A 12.8 A 16.0 A
98.4% 97.9% 8000 W 8000 W

60 A 16.0 A 16.0 A 20.0 A
<3% (of nominal power)
0.8 leading to 0.8 lagging III
98.4% 97.9%
10000 W 10000 W 120~600 V
30 A 30 A 30 A 30 A LiFePO4

(1) The voltage range meets the requirements of the corresponding national grid code. (2) The frequency range meets the requirements of the corresponding national grid code.

19.2 A 19.2 A 25.0 A
98.4% 97.9% 12000 W 12000 W

10.5 General data

Type

ASW05kH/06kH/08kH/10kH/12kH-T2 ASW05kH/06kH/08kH/10kH/12kH-T2-O

ASW08kH/10kH/12kH-T3 ASW08kH/10kH/12kH-T3-O

Width × height × depth

545 mm × 465 mm ×205 mm

Weight

24.7 kg

26.4 kg

Topology

Non-isolated

Operating temperature range Allowable relative humidity range (non-condensing) Degree of protection for electronics in accordance with IEC 60529 Climatic category in accordance with IEC 60721-3-4 Protection class (according to IEC 62103)
Pollution degree outside the enclosure
Pollution degree inside the enclosure
Max. operating altitude above mean sea level
Self-consumption (night)

-25 … +60 0% … 100%
IP66
4K4H I 3 2
4000 m (>3000 m derating) <10W

Cooling method

Natural convection

116

UM0077_ASW05-12kH-T2-T3(TCP version)_EN_V01_0425

Typical noise emission Display Demand response mode in accordance with AS/NZS 4777.2 Export active power output Earth Fault Alarm Interfaces Communication Mounting information Radio technology Radio spectrum Maximum transmission power AFCI type
10.6 Protective function
Protective function
DC reverse polarity protection DC isolator Ground fault monitoring AC short- circuit current capability Active anti-islanding protection PV string current monitoring DC current injection monitoring Low voltage ride through High voltage ride through Overvoltage protection

< 30 dB(A)@1m LED indicator, App

DRM0

Via connecting Smart meter

cloud based Visible ,
RS485, WiFi stick

ModBus RTU and CAN

Wall mounting bracket

WLAN 802.11 b/g/n

2.4 GHz

100 mW

F-I-AFPE-1-1-2

F-I-AFPE-1-1-3

ASW05kH/06kH/08kH/10kH/12kH-T2 ASW05kH/06kH/08kH/10kH/12kH-T2-O
ASW08kH/10kH/12kH-T3 ASW08kH/10kH/12kH-T3-O
Integrated Integrated Integrated Integrated Integrated Integrated Integrated
Integrated Integrated DC Type II / AC Type III

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11 Troubleshooting

When the PV system does not operate normally, we recommend the following solutions for quick troubleshooting. If an error or warning occurs, there will have “Event Messages” display in the LCD screen and monitor tools. The corresponding corrective measures are as follows:

Error code Message 1-6 Permanent Fault 8,9

Device fault

Abnormal

frequency

change

Grid frequency 33
fault

Grid voltage 34
fault

Grid loss

GFCI fault

PV over 37
voltage fault

Isolation fault

40 41,42

Over temperature fault
Self-diagnosis

Corrective measures
Disconnect the inverter from the batterythe grid and the PV array and reconnect after 3 minutes.
If this fault is still being shown, contact the service. The inverter temperature should above -40. Disconnect the inverter from the batterythe grid and the PV array and reconnect
after 3 minutes. If this fault is still being shown, contact the service. The inverter temperature should above -40.
Check if the grid is abnormal. Restart the inverter and wait until it functions normally. Contact customer service if error warning continues.
Check the grid and EPS frequency and observe how often major fluctuations occur. Contact customer service if EPS frequency abnormal. If this fault is caused by frequent fluctuations, try to modify the operating parameters after informing the grid operator first.
Check the grid voltage and grid connection on inverter. Check the grid voltage at the point of connection of inverter.
If the grid voltage is outside the permissible range due to local grid conditions, try to modify the values of the monitored operational limits after informing the electric utility company first. If the grid voltage lies within the permitted range and this fault still occurs, please call service. Check the fuse and the triggering of the circuit breaker in the distribution box. Check the grid voltage, grid usability. Check the AC cable, grid connection on the inverter. If this fault is still being shown, contact the service. Make sure the grounding connection of the inverter is reliable. Make a visual inspection of all PV cables and modules. If this fault is still shown, contact the service. Check the open-circuit voltages of the strings and make sure it is below the maximum DC input voltage of the inverter. If the input voltage lies within the permitted range and the fault still occurs, please call service. Check the PV array’s insulation to ground and make sure that the insulation resistance to ground is greater than 1 Mohm. Otherwise, make a visual inspection of all PV cables and modules. Make sure the grounding connection of the inverter is reliable. If this fault occurs often, contact the service.
Check whether the airflow to the heat sink is obstructed. Check whether the ambient temperature around the inverter is too high.
Disconnect the inverter from the batterythe grid and the PV array and reconnect

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48
65 69 72 73 79
W192

fault

Bus over

voltage

10 minutes average over voltage fault

PE wire connection fault
NS-protection fault

Parallel RS 485 Comm Fault Parallel CAN Comm Fault Parallel Multiple Host Fault

Meter or CT loss

after 3 minutes. If this fault is still being shown, contact the service. Check the input mode setting is correct. Restart the inverter and wait until it functions normally. Contact customer service if error warning continues. Check the grid voltage at the point of connection of inverter. If the grid voltage is outside the permissible range due to local grid conditions, try to modify the values of the monitored operational limits after informing the electric utility company first. If the grid voltage lies within the permitted range and this fault still occurs, please call service. Check if the ground line is connected with the inverter; Make sure the grounding connection of the inverter is connected and reliable. If this fault occurs often, contact the service. Please disable External input signal function in APP if inverter does not connect NSprotection device. Please check the cable of NS-protection deviceif the cable connection is normal, the NS-protection trigged.
Check comm line and 120ohm Resistors.
Check comm line and 120ohm Resistors.
Check host quantity and set one host.
If CT is enable, check the phase sequence , connector and Buckle of CT, The phase sequence of CT needs to be consistent with the grid and inverter; If meter is enable, check the meter screen, if there is no phone symbol on meter screen check the communication connection of meter; if there is phone symbol on meter screenplease re-plug the connector of meter. If this fault occurs often, contact the service

Contact the service if you meet other problems not in the table.

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12 Maintenance
12.1 Cleaning the contacts of the DC switch DANGER
High voltage of PV string may cause life danger If the DC connector is disconnected while the PV inverter is working, electric arc may occur, causing electric shock and burns. Please disconnect the circuit breaker on the AC side first, and then disconnect the DC switch.
To ensure the normal operation of the DC input switch, it is necessary to clean the DC switch contacts every year. Procedure:
Step 1 Disconnect the AC disconnector and prevent accidental restart.
Step 2 Rotate the DC switch handle from the “ON” position to the “OFF” position for 5 times.
12.2 Cleaning air inlet and outlet CAUTION
Hot enclosure or heat sink may cause personal injury! When the inverter is working, the temperature of the enclosure or heat sink will be higher than 70, and the contact may cause burns. Before cleaning the air outlet, shut down the machine and wait for about 30 minutes until the temperature of the enclosure
decreases to normal temperature.
A huge amount of heat is generated in the process of running the inverter. The inverter adopts a controlled forced-air cooling method. In order to maintain good ventilation, please check to make sure the air inlet and outlet are not blocked. Procedure:
Step 1 Disconnect the AC side circuit breaker and ensure that it cannot be accidentally reconnected.
Step 2 Disconnect the DC switch, rotate the DC switch handle from the “ON” position to the “OFF” position.
Step 3 Clean the air inlet and outlet of the inverter with a soft brush.

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13 Recycling and disposal
Dispose of the packaging and replaced parts according to the rules applicable in the country where the device is installed.

Do not dispose of the product together with the household waste but in accordance with the disposal regulations for electronic waste applicable at the installation site.
14 EU declaration of conformity
Within the scope of the EU directives · Radio Equipment Directive 2014/53/EU (L 153/62-106. May 22. 2014) (RED) · Restriction of the use of certain hazardous substances 2011/65/EU (L 174/88, June 8, 2011) and 2015/863/EU (L 137/10, March 31,2015) (RoHS) AISWEI Technology Co., Ltd. confirms herewith that the inverters described in this manual are in compliance with the fundamental requirements and other relevant provisions of the above mentioned directives. The entire EU Declaration of Conformity can be found at www.solplanet.net.
15 Service and warranty
If you have any technical problems concerning our products, please contact Solplanet service. We require the following information in order to provide you with the necessary assistance: · Inverter device type · Inverter serial number · Type and number of connected PV modules · Error code · Mounting location · Installation date · Warranty card
Warranty terms and conditions can be downloaded at www.solplanet.net. When the customer needs warranty service during the warranty period, the customer must pro- vide a copy of the invoice, factory warranty card, and ensure the electrical label of the inverter is legible. If these conditions are not met, Solplanet has the right to refuse to provide with the relevant warranty service.

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16 Contact
EMEA Service email: service.EMEA@solplanet.net
APAC Service email: service.APAC@solplanet.net
LATAM Service email: service.LATAM@solplanet.net
AISWEI Pty Ltd. Hotline: +61 390 988 674 Add.: Level 40, 140 William Street, Melbourne VIC 3000, Australia
AISWEI B.V. Hotline: +31 208 004 844 (Netherlands) +48 134 926 109 (Poland) Add.: Barbara Strozzilaan 101,5e etage,kantoornummer 5.12,1083HN Amsterdam,the Netherlands
AISWEI Technology Co., Ltd Hotline: +86 400 801 9996 Add.: No. 18, Alley 600, Nanchezhan Road, Huangpu District, Shanghai, China
https://solplanet.net/contact-us/

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Documents / Resources

Solplanet ASW 05-12kH-T2 Three Phase Hybrid Inverter [pdf] User Manual
ASW 05-12kH-T2, ASW 05-12kH-T3, ASW 05-12kH-T2 Three Phase Hybrid Inverter, ASW 05-12kH-T2, Three Phase Hybrid Inverter, Hybrid Inverter, Inverter

References

User Manual

ASW 05-12kH-T2 Three Phase Hybrid Inverter

Specifications

Product Usage Instructions

1. General Information

2. Safety

3. Unpacking and Storage

5. Mounting

7. Commissioning and Operating

8. Solplanet APP

FAQ

Q: Who is the target group for this product?

Documents / Resources

References

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