Manuals+

USER MANUAL

3.5KW/5.5KW PLUS

INVERTER / MPPT SCC / AC CHARGER

VERSION: 1.0

1 ABOUT THIS MANUAL

This manual describes the assembly, installation, operation, and troubleshooting of this unit. Please read this manual carefully before installations and operations. Keep this manual for future reference.

This manual provides safety and installation guidelines as well as information on tools and wiring.

2 SAFETY INSTRUCTIONS

WARNING: This chapter contains important safety and operating instructions. Read and keep this manual for future reference.

  1. Before using the unit, read all instructions and cautionary markings on the unit, the batteries, and all appropriate sections of this manual.
  2. CAUTION --To reduce risk of injury, charge only deep-cycle lead acid type rechargeable batteries. Other types of batteries may burst, causing personal injury and damage.
  3. Do not disassemble the unit. Take it to a qualified service center when service or repair is required. Incorrect re-assembly may result in a risk of electric shock or fire.
  4. To reduce risk of electric shock, disconnect all wirings before attempting any maintenance or cleaning. Turning off the unit will not reduce this risk.
  5. CAUTION – Only qualified personnel can install this device with battery.
  6. NEVER charge a frozen battery.
  7. For optimum operation of this inverter/charger, please follow required spec to select appropriate cable size. It's very important to correctly operate this inverter/charger.
  8. Be very cautious when working with metal tools on or around batteries. A potential risk exists to drop a tool to spark or short circuit batteries or other electrical parts and could cause an explosion.
  9. Please strictly follow installation procedure when you want to disconnect AC or DC terminals. Please refer to INSTALLATION section of this manual for the details.
  10. One piece of 150A fuse is provided as over-current protection for the battery supply.
  11. GROUNDING INSTRUCTIONS - This inverter/charger should be connected to a permanent grounded wiring system. Be sure to comply with local requirements and regulation to install this inverter.
  12. NEVER cause AC output and DC input short circuited. Do NOT connect to the mains when DC input short circuits.
  13. Warning!! Only qualified service persons are able to service this device. If errors still persist after following troubleshooting table, please send this inverter/charger back to local dealer or service center for maintenance.

3 INTRODUCTION

This is a multi-function inverter/charger, combining functions of inverter, solar charger, and battery charger to offer uninterruptible power support with portable size. Its comprehensive LCD display offers user-configurable and easy-accessible button operation such as battery charging current, AC/solar charger priority, and acceptable input voltage based on different applications.

3.1 Features

3.2 Basic System Architecture

The following illustration shows basic application for this inverter/charger. It also includes following devices to have a complete running system:

Consult with your system integrator for other possible system architectures depending on your requirements.

This inverter can power all kinds of appliances in home or office environment, including motor-type appliances such as tube light, fan, refrigerator, and air conditioner.

Diagram: A hybrid power system diagram showing solar panels connected to the inverter, a generator/utility connection to the inverter, external battery packs connected to the inverter, and home appliances connected to the inverter's output.

3.3 Product Overview

Diagram: Figure 1 Hybrid Power System showing the inverter unit with numbered components.

Component List:

4 INSTALLATION

4.1 Unpacking and Inspection

Before installation, please inspect the unit. Be sure that nothing inside the package is damaged. You should have received the following items inside of package:

4.2 Preparation

Before connecting all wirings, please take off the bottom cover by removing two screws as shown below.

Diagram: Illustration showing how to remove the bottom cover by unscrewing two screws.

4.3 Mounting the Unit

Consider the following points before selecting where to install:

Diagram: Illustration showing the unit with recommended clearance dimensions: 20cm side, 50cm top/bottom.

NOTICE: SUITABLE FOR MOUNTING ON CONCRETE OR OTHER NON-COMBUSTIBLE SURFACE ONLY.

Install the unit by screwing two screws. It's recommended to use M4 or M5 screws.

4.4 Battery Connection

CAUTION: For safety operation and regulation compliance, it's requested to install a separate DC over-current protector or disconnect device between battery and inverter. It may not be requested to have a disconnect device in some applications, however, it's still requested to have over-current protection installed. Please refer to typical amperage in below table as required fuse or breaker size.

WARNING! All wiring must be performed by a qualified personnel.

WARNING! It's very important for system safety and efficient operation to use appropriate cable for battery connection. To reduce risk of injury, please use the proper recommended cable as below.

Recommended battery cable size:

Model Wire Size Cable (mm²) Torque value (max)
3.5KW/5.5KW 1 x 2AWG 35 2 Nm

Please follow below steps to implement battery connection:

  1. Remove insulation sleeve 18 mm for positive and negative conductors.
  2. Suggest to put bootlace ferrules on the end of positive and negative wires with a proper crimping tool.
  3. Fix strain relief plate to the inverter by supplied screws as shown in below chart.

Diagram: Illustration showing insulation removal and ferrule application.

Diagram: Illustration showing strain relief plate attachment.

Diagram: Battery connection diagrams for 3.5KW (two 12V batteries in series) and 5.5KW (four 12V batteries in series).

5. Insert the battery wires flatly into battery connectors of inverter and make sure the bolts are tightened with torque of 2 Nm in clockwise direction. Make sure polarity at both the battery and the inverter/charge is correctly connected and conductors are tightly screwed into the battery terminals.

Recommended tool: #2 Pozi Screwdriver

6. To firmly secure wire connection, you may fix the wires to strain relief with cable tie.

WARNING: Shock Hazard

Installation must be performed with care due to high battery voltage in series.

CAUTION!! Before making the final DC connection or closing DC breaker/disconnector, be sure positive (+) must be connected to positive (+) and negative (-) must be connected to negative (-).

4.5 AC Input/Output Connection

CAUTION!! Before connecting to AC input power source, please install a separate AC breaker between inverter and AC input power source. This will ensure the inverter can be securely disconnected during maintenance and fully protected from over current of AC input. The recommended spec of AC breaker is 32A for 3.5KW and 50A for 5.5KW.

CAUTION!! There are two terminal blocks with “IN” and “OUT” markings. Please do NOT mis-connect input and output connectors.

WARNING! All wiring must be performed by a qualified personnel.

WARNING! It's very important for system safety and efficient operation to use appropriate cable for AC input connection. To reduce risk of injury, please use the proper recommended cable size as below.

Suggested cable requirement for AC wires

Model Gauge Cable (mm²) Torque Value
3.5KW 12 AWG 4 1.2 Nm
5.5KW 10 AWG 6 1.2 Nm

Please follow below steps to implement AC input/output connection:

  1. Before making AC input/output connection, be sure to open DC protector or disconnector first.
  2. Remove insulation sleeve 10mm for six conductors. And shorten phase L and neutral conductor N 3 mm.
  3. Insert AC input wires according to polarities indicated on terminal block and tighten the terminal screws. Be sure to connect PE protective conductor (Ground: yellow-green) first.
  4. Diagram: Illustration showing AC input terminal block wiring with Ground, Line, and Neutral connections.
  5. WARNING: Be sure that AC power source is disconnected before attempting to hardwire it to the unit.
  6. Then, insert AC output wires according to polarities indicated on terminal block and tighten terminal screws. Be sure to connect PE protective conductor (Ground: yellow-green) first.
  7. Diagram: Illustration showing AC output terminal block wiring with Ground, Line, and Neutral connections.
  8. Make sure the wires are securely connected.

CAUTION: Appliances such as air conditioner are required at least 2~3 minutes to restart because it's required to have enough time to balance refrigerant gas inside of circuits. If a power shortage occurs and recovers in a short time, it will cause damage to your connected appliances. To prevent this kind of damage, please check manufacturer of air conditioner if it's equipped with time-delay function before installation. Otherwise, this inverter/charger will trig overload fault and cut off output to protect your appliance but sometimes it still causes internal damage to the air conditioner.

4.6 PV Connection

CAUTION: Before connecting to PV modules, please install separately a DC circuit breaker between inverter and PV modules.

WARNING! It's very important for system safety and efficient operation to use appropriate cable for PV module connection. To reduce risk of injury, please use the proper recommended cable size as below.

PV Module Connection Cable Requirement:

Model Wire Size Cable (mm²) Torque value (max)
3.5KW/5.5KW 1 x 12AWG 4 1.2 Nm

PV Module Selection:

When selecting proper PV modules, please be sure to consider below parameters:

  1. Open circuit Voltage (Voc) of PV modules not exceeds max. PV array open circuit voltage of inverter.
  2. Open circuit Voltage (Voc) of PV modules should be higher than min. battery voltage.
INVERTER MODEL 3.5KW 5.5KW
Max. PV Array Open Circuit Voltage 500Vdc 500Vdc
PV Array MPPT Voltage Range 120Vdc~450Vdc 120Vdc~450Vdc

Take 250Wp PV module as an example. After considering above two parameters, the recommended module configurations are listed as below table.

Solar Panel Spec. (reference) SOLAR INPUT (Min in serial: 6 pcs, max. in serial: 13 pcs) Q'ty of panels Total input power
250Wp
Vmp: 30.1Vdc
Imp: 8.3A
Voc: 37.7Vdc
Isc: 8.4A
Cells: 60		 6 pcs in serial 6 pcs 1500W
8 pcs in serial 8 pcs 2000W
12 pcs in serial 12 pcs 3000W
13 pcs in serial 13 pcs 3250W
8 pieces in serial and 2 sets in parallel 16 pcs 4000W
10 pieces in serial and 2 sets in parallel 20 pcs 5000W

PV Module Wire Connection

Please follow below steps to implement PV module connection:

  1. Remove insulation sleeve 10 mm for positive and negative conductors.
  2. Suggest to put bootlace ferrules on the end of positive and negative wires with a proper crimping tool.
  3. Fix PV wire cover to the inverter with supplied screws as shown in below chart.

Diagram: Illustration showing PV wire connection and cover attachment.

4. Check correct polarity of wire connection from PV modules and PV input connectors. Then, connect positive pole (+) of connection wire to positive pole (+) of PV input connector. Connect negative pole (-) of connection wire to negative pole (-) of PV input connector. Screw two wires tightly in clockwise direction.

Recommended tool: 4mm blade screwdriver

4.7 Final Assembly

After connecting all wirings, please put bottom cover back by screwing two screws as shown below.

Diagram: Illustration showing the unit with the bottom cover re-attached.

4.8 Communication Connection

  1. Please use supplied communication cable to connect to inverter and PC. Insert bundled CD into a computer and follow on-screen instruction to install the monitoring software. For the detailed software operation, please check user manual of software inside of CD.
  2. Wi-Fi cloud communication (option): Please use supplied communication cable to connect to inverter and Wi-Fi module. Download APP and install from APP store, and Refer to “Wi-Fi Plug Quick Installation Guideline" to set up network and registering. The inverter status would be shown by mobile phone APP or webpage of computer.
  3. GPRS cloud communication (option): Please use supplied communication cable to connect to inverter and GPRS module, and then applied external power to GPRS module. Download APP and install from APP store, and Refer to “GPRS RTU Quick Installation Guideline" to set up network and registering. The inverter status would be shown by mobile phone APP or webpage of computer.

5 OPERATION

5.1 Power ON/OFF

Diagram: Side view of the unit showing the power on/off switch.

Once the unit has been properly installed and the batteries are connected well, simply press On/Off switch (located on the button of the case) to turn on the unit.

5.2 Operation and Display Panel

The operation and display panel, shown in below chart, is on the front panel of the inverter. It includes three indicators, four function keys, and a LCD display, indicating the operating status and input/output power information.

Diagram: Front panel of the inverter showing LCD Display and LED Indicators.

LED Indicator

LED Indicator Color Messages
AC/INV Green Solid On: Output is powered by utility in Line mode.
Flashing: Output is powered by battery or PV in battery mode.
CHG Green Solid On: Battery is fully charged.
Flashing: Battery is charging.
FAULT Red Solid On: Fault occurs in the inverter.
Flashing: Warning condition occurs in the inverter.

Function Keys

Function Key Description
ESC To exit setting mode
UP To go to previous selection
DOWN To go to next selection
ENTER To confirm the selection in setting mode or enter setting mode

5.3 LCD Display Icons

Input Source Information:

Input/Battery/Output Information:

Configuration Program and Fault Information:

Battery Information:

In AC mode, it will present battery charging status.

Status Battery voltage LCD Display
Constant <2V/cell 4 bars will flash in turns.
Constant 2 ~ 2.083V/cell Bottom bar will be on and the other three bars will flash in turns.
Current mode / Voltage mode 2.083 ~ 2.167V/cell Bottom two bars will be on and the other two bars will flash in turns.
> 2.167 V/cell Bottom three bars will be on and the top bar will flash.

Floating mode. Batteries are fully charged. 4 bars will be on.

In battery mode, it will present battery capacity.

Load Percentage Battery Voltage LCD Display
Load >50% < 1.85V/cell Diagram: Battery icon with 1 bar filled.
1.85V/cell ~ 1.933V/cell Diagram: Battery icon with 2 bars filled.
1.933V/cell ~ 2.017V/cell Diagram: Battery icon with 3 bars filled.
> 2.017V/cell Diagram: Battery icon with 4 bars filled.
Load < 50% < 1.892V/cell Diagram: Battery icon with 1 bar filled.
1.892V/cell ~ 1.975V/cell Diagram: Battery icon with 2 bars filled.
1.975V/cell ~ 2.058V/cell Diagram: Battery icon with 3 bars filled.
> 2.058V/cell Diagram: Battery icon with 4 bars filled.

Load Information

Mode Operation Information:

Mute Operation

5.4 LCD Setting

After pressing and holding ENTER button for 3 seconds, the unit will enter setting mode. Press “UP" or “DOWN" button to select setting programs. And then, press “ENTER” button to confirm the selection or ESC button to exit.

Setting Programs:

Program Description Selectable option Explanation
00 Exit setting mode ESC
01 Output source priority:
To configure load power source priority		 Utility first (default) Utility will provide power to the loads as first priority.
Solar and battery energy will provide power to the loads only when utility power is not available.
Solar first Solar energy provides power to the loads as first priority.
If solar energy is not sufficient to power all connected loads, utility will supply power to the loads at the same time.
SBU priority Battery provides power to the loads only when any one condition happens:
- Solar energy and utility is not available.
- Solar energy is not sufficient and utility is not available.
Solar energy provides power to the loads as first priority.
If solar energy is not sufficient to power all connected loads, battery energy will supply power to the loads at the same time.
Utility provides power to the loads only when battery voltage drops to either low-level warning voltage or the setting point in program 12.
02 Maximum charging current:
To configure total charging current for solar and utility chargers.
(Max. charging current = utility charging current + solar charging current)		 10A
20A
30A
40A
50A
60A (default)
70A
80A
90A
100A
03 AC input voltage range Appliances (default) If selected, acceptable AC input voltage range will be within 90-280VAC.
UPS If selected, acceptable AC input voltage range will be within 170-280VAC.
05 Battery type AGM (default) If "User-Defined" is selected, battery charge voltage and low DC cut-off voltage can be set up in program 26, 27 and 29.
Flooded
06 Auto restart when overload occurs Restart disable (default) Restart enable
Restart enable
07 Auto restart when over temperature occurs Restart disable (default) Restart enable
Restart enable
09 Output frequency 50Hz (default) 60Hz
60Hz
10 Output voltage 220V 230V (default)
240V 230V
11 Maximum utility charging current 2A 10A
20A 20A
40A 50A
60A 80A
12 Setting voltage point back to utility source when selecting "SBU priority" or "Solar first" in program 01. 22.0V 22.5V
23.0V (default) 23.5V
24.0V 24.5V
25.0V 25.5V
Available options in 5.5KW model:
44V 45V
46V (default) 47V
48V 49V
50V 51V
52V 53V
13 Setting voltage point back to battery mode when selecting "SBU priority" or "Solar first" in program 01. Battery fully charged 24V
24.5V 25V
25.5V 26V
26.5V 27V (default)
27.5V 28V
28.5V 29V
Available options in 5.5KW model:
Battery fully charged 48V
49V 50V
51V 52V
53V 54V (default)
55V 56V
57V 58V
16 Charger source priority:
To configure charger source priority		 Utility first Utility will charge battery as first priority.
Solar energy will charge battery only when utility power is not available.
Solar first Solar energy will charge battery as first priority.
Utility will charge battery only when solar energy is not available.
Solar and Utility (default) Solar energy and utility will charge battery at the same time.
Only Solar Solar energy will be the only charger source no matter utility is available or not.
If this inverter/charger is working in Battery mode or Power saving mode, only solar energy can charge battery. Solar energy will charge battery if it's available and sufficient.
18 Alarm control Alarm on (default) Alarm off
Alarm off
19 Auto return to default display screen Return to default display screen (default) If selected, no matter how users switch display screen, it will automatically return to default display screen (Input voltage /output voltage) after no button is pressed for 1 minute.
Stay at latest screen If selected, the display screen will stay at latest screen user finally switches.
20 Backlight control Backlight on (default) Backlight off
Backlight off
22 Beeps while primary source is interrupted Alarm on (default) Alarm off
Alarm off
23 Overload bypass:
When enabled, the unit will transfer to line mode if overload occurs in battery mode.		 Bypass disable (default) Bypass enable
Bypass enable
25 Record Fault code Record enable (default) Record disable
Record disable
26 Bulk charging voltage
(C.V voltage)		 3.5KW default setting: 28.2V 5.5KW default setting: 56.4V
If self-defined is selected in program 5, this program can be set up. Setting range is from 25.0V to 31.5V for 3.5KW model and 48.0V to 61.0V for 5.5KW model. Increment of each click is 0.1V.
27 Floating charging voltage 3.5KW default setting: 27.0V 5.5KW default setting: 54.0V
If self-defined is selected in program 5, this program can be set up. Setting range is from 25.0V to 31.5V for 3.5KW model and 48.0V to 61.0V for 5.5KW model. Increment of each click is 0.1V.
29 Low DC cut-off voltage 3.5KW default setting: 20.0V 5.5KW default setting: 40.0V
If self-defined is selected in program 5, this program can be set up. Setting range is from 21.0V to 24.0V for 3.5KW model and 42.0V to 48.0V for 5.5KW model. Increment of each click is 0.1V. Low DC cut-off voltage will be fixed to setting value no matter what percentage of load is connected.
30 Battery equalization Battery equalization enable (default) Battery equalization disable (default)
Battery equalization disable
31 Battery equalization voltage 3.5KW default setting: 29.2V 5.5KW default setting: 58.4V
Setting range is from 25.0V to 31.5V for 3.5KW model and 48.0V to 61.0V for 5.5KW model. Increment of each click is 0.1V.
33 Battery equalized time 60min (default) Setting range is from 5min to 900min. Increment of each click is 5min.
34 Battery equalized timeout 120min (default) Setting range is from 5min to 900 min. Increment of each click is 5 min.
35 Equalization interval 30days (default) Setting range is from 0 to 90 days. Increment of each click is 1 day
36 Equalization activated immediately Enable Disable (default)
Disable If equalization function is enabled in program 30, this program can be set up. If "Enable" is selected in this program, it's to activate battery equalization immediately and LCD main page will shows "E9". If "Disable" is selected, it will cancel equalization function until next activated equalization time arrives based on program 35 setting. At this time, "E9" will not be shown in LCD main page.
50 AC charger ON timer AC charger start from 00:00 to 23:00. (Default 00:00)
51 AC charger OFF timer AC charger stops from 00:00 to 23:00. (Default 00:00)
52 AC output ON timer AC output on from 00:00 to 23:00. (Default 00:00)
53 AC output OFF timer AC output off from 00:00 to 23:00. (Default 00:00)
54 Real time setting---Minute Default 00, range 00~59
55 Real time setting---Hour Default 00, range 00~23
56 Real time setting---Date Default 01, range 01~31
57 Real time setting---Month Default 01, range 01~12
58 Real time setting---Year Default 16, range 16~99

5.5 Display Setting

The LCD display information will be switched in turns by pressing “UP” or “DOWN” key. The selectable information is switched as below order: input voltage, input frequency, PV voltage, charging current, charging power, battery voltage, output voltage, output frequency, load percentage, load in Watt, load in VA, load in Watt, DC discharging current, main CPU Version.

Selectable information

LCD display

Input voltage/Output voltage
(Default Display Screen)		 Diagram: LCD showing Input Voltage=230V, Output voltage=230V. Includes AC, PV, BYPASS, CHARGING icons and load percentage indicators (100%, 25%).
Input frequency Diagram: LCD showing Input frequency=50Hz. Includes AC, PV, BYPASS, CHARGING icons and load percentage indicators (100%, 25%).
PV voltage Diagram: LCD showing PV voltage=260V, Output=230V. Includes AC, PV, BYPASS, CHARGING icons and load percentage indicators (100%, 25%).
PV current Diagram: LCD showing PV current = 2.5A, Output=230V. Includes AC, PV, BYPASS, CHARGING icons and load percentage indicators (100%, 25%).
PV power Diagram: LCD showing PV power = 500W, Output=230V. Includes AC, PV, BYPASS, CHARGING icons and load percentage indicators (100%, 25%).
Charging current AC and PV charging current=50A
Diagram: LCD showing BATT current 50A, OUTPUT 230V. Includes AC, PV, BYPASS, CHARGING icons and load percentage indicators (100%, 25%).
PV charging current=50A
Diagram: LCD showing BATT current 50A, OUTPUT 230V. Includes PV, BYPASS, CHARGING icons and load percentage indicators (100%, 25%).
AC charging current=50A
Diagram: LCD showing BATT current 50A, OUTPUT 230V. Includes AC, BYPASS, CHARGING icons and load percentage indicators (100%, 25%).
Charging power AC and PV charging power=500W
Diagram: LCD showing BATT 500W, OUTPUT 230V. Includes AC, PV, BYPASS, CHARGING icons and load percentage indicators (100%, 25%).
PV charging power=500W
Diagram: LCD showing BATT 500W, OUTPUT 230V. Includes PV, BYPASS, CHARGING icons and load percentage indicators (100%, 25%).
AC charging power=500W
Diagram: LCD showing BATT 500W, OUTPUT 230V. Includes AC, BYPASS, CHARGING icons and load percentage indicators (100%, 25%).
Battery voltage and output voltage Battery voltage=25.5V, output voltage=230V
Diagram: LCD showing BATT 25.5V, OUTPUT 230V. Includes AC, PV, BYPASS, CHARGING icons and load percentage indicators (100%, 25%).
Output frequency Output frequency=50Hz
Diagram: LCD showing BATT 25.5V, OUTPUT 50.0Hz. Includes AC, PV, BYPASS, CHARGING icons and load percentage indicators (100%, 25%).
Load percentage Load percent=70%
Diagram: LCD showing BATT 25.5V, LOAD 70%. Includes AC, PV, BYPASS, CHARGING icons and load percentage indicators (100%, 25%).
Load in VA When connected load is lower than 1kVA, load in VA will present xxxVA like below chart.
Diagram: LCD showing BATT 25.5V, LOAD 350VA. Includes AC, PV, BYPASS, CHARGING icons and load percentage indicators (100%, 25%).
When load is larger than 1kVA (≥ 1KVA), load in VA will present x.xkVA like below chart.
Diagram: LCD showing BATT 25.5V, LOAD 1.50kVA. Includes AC, PV, BYPASS, CHARGING icons and load percentage indicators (100%, 25%).
Load in Watt When load is lower than 1kW, load in W will present xxxW like below chart.
Diagram: LCD showing BATT 25.5V, LOAD 270W. Includes AC, PV, BYPASS, CHARGING icons and load percentage indicators (100%, 25%).
When load is larger than 1kW (≥1KW), load in W will present x.xkW like below chart.
Diagram: LCD showing BATT 25.5V, LOAD 1.20kW. Includes AC, PV, BYPASS, CHARGING icons and load percentage indicators (100%, 25%).
Battery voltage/DC discharging current Battery voltage=25.5V, discharging current=1A
Diagram: LCD showing BATT 25.5V, BATT 1A. Includes AC, PV, BYPASS, CHARGING icons and load percentage indicators (100%, 25%).

Main CPU version checking:

Diagram: LCD showing Main CPU version 20 09.

5.6 Operating Mode Description

Operation mode Description LCD display
Standby mode / Power saving mode
Note:
*Standby mode: The inverter is not turned on yet but at this time, the inverter can charge battery without AC output.
*Power saving mode: If enabled, the output of inverter will be off when connected load is pretty low or not detected.		 No output is supplied by the unit but it still can charge batteries. Diagram: LCD showing Charging by utility and PV energy.
Diagram: LCD showing Charging by utility.
Diagram: LCD showing Charging by PV energy.
Diagram: LCD showing No charging.
Fault mode
Note:
*Fault mode: Errors are caused by inside circuit error or external reasons such as over temperature, output short circuited and so on.		 PV energy and utility can charge batteries. Diagram: LCD showing Charging by utility and PV energy.
Diagram: LCD showing Charging by utility.
Diagram: LCD showing Charging by PV energy.
Diagram: LCD showing No charging.
Line Mode The unit will provide output power from the mains. It will also charge the battery at line mode. Diagram: LCD showing Charging by utility and PV energy.
Diagram: LCD showing Charging by utility.
The unit will provide output power from the mains. It will also charge the battery at line mode. If "solar first" is selected as output source priority and solar energy is not sufficient to provide the load, solar energy and the utility will provide the loads and charge the battery at the same time.
If "solar first" is selected as output source priority and battery is not connected, solar energy and the utility will provide the loads.
Diagram: LCD showing Power from utility.
Battery Mode The unit will provide output power from battery and PV power. Diagram: LCD showing Power from battery and PV energy.
PV energy will supply power to the loads and charge battery at the same time.
The unit will provide output power from battery and PV power. Diagram: LCD showing Power from battery only.
Diagram: LCD showing Power from PV energy only.

5.7 Battery Equalization Description

Equalization function is added into charge controller. It reverses the buildup of negative chemical effects like stratification, a condition where acid concentration is greater at the bottom of the battery than at the top. Equalization also helps to remove sulfate crystals that might have built up on the plates. If left unchecked, this condition, called sulfation, will reduce the overall capacity of the battery. Therefore, it's recommended to equalize battery periodically.

How to Apply Equalization Function

You must enable battery equalization function in monitoring LCD setting program 30 first. Then, you may apply this function in device by either one of following methods:

  1. Setting equalization interval in program 35.
  2. Active equalization immediately in program 36.

When to Equalize

In float stage, when the setting equalization interval (battery equalization cycle) is arrived, or equalization is active immediately, the controller will start to enter Equalize stage.

Diagram: Graph showing battery charging stages (BULK, ABSORPTION, FLOAT, EQUALIZE, FLOAT) with voltage progression over time.

Equalize charging time and timeout

In Equalize stage, the controller will supply power to charge battery as much as possible until battery voltage raises to battery equalization voltage. Then, constant-voltage regulation is applied to maintain battery voltage at the battery equalization voltage. The battery will remain in the Equalize stage until setting battery equalized time is arrived.

However, in Equalize stage, when battery equalized time is expired and battery voltage doesn't rise to battery equalization voltage point, the charge controller will extend the battery equalized time until battery voltage achieves battery equalization voltage. If battery voltage is still lower than battery equalization voltage when battery equalized timeout setting is over, the charge controller will stop equalization and return to float stage.

Diagram: Graph showing battery charging stages with equalization timeout, illustrating voltage progression over time.

5.8 Fault Reference Code

Fault Code Fault Event Icon on
01 Fan is locked when inverter is off. Diagram: Icon 01.
02 Over temperature Diagram: Icon 02.
03 Battery voltage is too high Diagram: Icon 03.
04 Battery voltage is too low Diagram: Icon 04.
05 Output short circuited or over temperature is detected by internal converter components. Diagram: Icon 05.
06 Output voltage is too high. Diagram: Icon 06.
07 Overload time out Diagram: Icon 07.
08 Bus voltage is too high Diagram: Icon 08.
09 Bus soft start failed Diagram: Icon 09.
51 Over current or surge Diagram: Icon 51.
52 Bus voltage is too low Diagram: Icon 52.
53 Inverter soft start failed Diagram: Icon 53.
55 Over DC voltage in AC output Diagram: Icon 55.
57 Current sensor failed Diagram: Icon 57.
58 Output voltage is too low Diagram: Icon 58.
59 PV voltage is over limitation Diagram: Icon 59.

5.9 Warning Indicator

Warning Code Warning Event Audible Alarm Icon flashing
01 Fan is locked when inverter is on. Beep three times every second Diagram: Icon 01 flashing.
03 Battery is over-charged Beep once every second Diagram: Icon 03 flashing.
04 Low battery Beep once every second Diagram: Icon 04 flashing.
07 Overload Beep once every 0.5 second Diagram: Icon OVER LOAD flashing.
10 Output power derating Beep twice every 3 seconds Diagram: Icon 10 flashing.
15 PV energy is low. Beep twice every 3 seconds Diagram: Icon 15 flashing.
E9 Battery equalization None Diagram: Icon E9 flashing.
6P Battery is not connected None Diagram: Icon 6P flashing.

6 CLEARANCE AND MAINTENANCE FOR ANTI-DUST KIT

6.1 Overview

Every inverter is already installed with anti-dusk kit from factory. Inverter will automatically detect this kit and activate internal thermal sensor to adjust internal temperature. This kit also keeps dusk from your inverter and increases product reliability in harsh environment.

6.2 Clearance and Maintenance

Step 1: Please loosen the screw in counterclockwise direction on the top of the inverter.

Diagram: Illustration showing screws on top of the inverter to be loosened.

Step 2: Then, dustproof case can be removed and take out air filter foam as shown in below chart.

Diagram: Illustration showing the dustproof case being removed and air filter foam extracted.

Step 3: Clean air filter foam and dustproof case. After clearance, re-assemble the dust-kit back to the inverter.

NOTICE: The anti-dust kit should be cleaned from dust every one month.

7 SPECIFICATIONS

Table 1 Line Mode Specifications

INVERTER MODEL 3.5KW 5.5KW
Input Voltage Waveform Sinusoidal (utility or generator)
Nominal Input Voltage 230Vac
Low Loss Voltage 170Vac±7V (UPS);
90Vac±7V (Appliances)
Low Loss Return Voltage 180Vac±7V (UPS);
100Vac±7V (Appliances)
High Loss Voltage 280Vac±7V
High Loss Return Voltage 270Vac±7V
Max AC Input Voltage 300Vac
Nominal Input Frequency 50Hz / 60Hz (Auto detection)
Low Loss Frequency 40±1Hz
Low Loss Return Frequency 42±1Hz
High Loss Frequency 65±1Hz
High Loss Return Frequency 63±1Hz
Output Short Circuit Protection Circuit Breaker
Efficiency (Line Mode) >95% (Rated R load, battery full charged)
Transfer Time 10ms typical (UPS);
20ms typical (Appliances)
Output power derating:
When AC input voltage drops to 170V, the output power will be derated.		 Diagram: Graph showing Output Power vs. Input Voltage. Rated Power is constant until 170V, then derates to 50% Power at 90V.

Table 2 Inverter Mode Specifications

INVERTER MODEL 3.5KW 5.5KW
Rated Output Power 3.5KW 5.5KW
Output Voltage Waveform Pure Sine Wave
Output Voltage Regulation 230Vac±5%
Output Frequency 50Hz
Peak Efficiency 93%
Overload Protection 5s@≥150% load; 10s@110%~150% load
Surge Capacity 2* rated power for 5 seconds
Nominal DC Input Voltage 24Vdc 48Vdc
Cold Start Voltage 23.0Vdc 46.0Vdc
Low DC Warning Voltage @load < 50%: 22.0Vdc
@load ≥ 50%: 21.0Vdc		 @load < 50%: 44.0Vdc
@load ≥ 50%: 42.0Vdc
Low DC Warning Return Voltage @load < 50%: 22.5Vdc
@load ≥ 50%: 22.0Vdc		 @load < 50%: 45.0Vdc
@load ≥ 50%: 44.0Vdc
Low DC Cut-off Voltage @load < 50%: 20.5Vdc
@load ≥ 50%: 20.0Vdc		 @load < 50%: 41.0Vdc
@load ≥ 50%: 40.0Vdc
High DC Recovery Voltage 32Vdc 62Vdc
High DC Cut-off Voltage 33Vdc 63Vdc
No Load Power Consumption <35W

Table 3 Charge Mode Specifications

Utility Charging Mode

INVERTER MODEL 3.5KW 5.5KW
Charging Algorithm 3-Step
AC Charging Current (Max) 80Amp (@VI/P=230Vac) 80Amp (@VI/P=230Vac)
Bulk Charging Voltage Flooded Battery: 29.2V
AGM / Gel Battery: 28.2V		 Flooded Battery: 58.4V
AGM / Gel Battery: 56.4V
Floating Charging Voltage 27Vdc 54Vdc
Charging Curve Diagram: Graph showing Charging Curve with Voltage and Current vs. Time, illustrating Bulk, Absorption, and Maintenance stages.

MPPT Solar Charging Mode

INVERTER MODEL 3.5KW 5.5KW
Max. PV Array Power 5000W 6000W
Nominal PV Voltage 240Vdc
PV Array MPPT Voltage Range 120~450Vdc
Max. PV Array Open Circuit Voltage 500Vdc
Max Charging Current (AC charger plus solar charger) 100Amp 100Amp

Table 4 General Specifications

INVERTER MODEL 3.5KW 5.5KW
Safety Certification CE
Operating Temperature Range -10°C to 50°C
Storage temperature -15°C~60°C
Humidity 5% to 95% Relative Humidity (Non-condensing)
Dimension (D*W*H), mm 100 x 300 x 440
Net Weight, kg 9.5 9.7

8 TROUBLE SHOOTING

Problem LCD/LED/Buzzer Explanation / Possible cause What to do
Unit shuts down automatically during startup process. LCD/LEDs and buzzer will be active for 3 seconds and then complete off. The battery voltage is too low (<1.91V/Cell) 1. Re-charge battery.
2. Replace battery.
No response after power on. No indication. 1. The battery voltage is far too low. (<1.4V/Cell)
2. Internal fuse tripped.		 1. Contact repair center for replacing the fuse.
2. Re-charge battery.
3. Replace battery.
Mains exist but the unit works in battery mode. Input voltage is displayed as 0 on the LCD and green LED is flashing. Input protector is tripped Check if AC breaker is tripped and AC wiring is connected well.
Green LED is flashing. Insufficient quality of AC power. (Shore or Generator) 1. Check if AC wires are too thin and/or too long.
2. Check if generator (if applied) is working well or if input voltage range setting is correct. (UPS Appliance)
Green LED is flashing. Set "Solar First" as the priority of output source. Change output source priority to Utility first.
When the unit is turned on, internal relay is switched on and off repeatedly. LCD display and LEDs are flashing Battery is disconnected. Check if battery wires are connected well.
Buzzer beeps continuously and red LED is on. Fault code 07 Overload error. The inverter is overload 110% and time is up. Reduce the connected load by switching off some equipment.
Fault code 05 Output short circuited. Check if wiring is connected well and remove abnormal load.
Fault code 02 Temperature of internal converter component is over 120°C.
Internal temperature of inverter component is over 100°C.		 Check whether the air flow of the unit is blocked or whether the ambient temperature is too high.
Fault code 03 Battery is over-charged. Return to repair center.
Check if spec and quantity of batteries are meet requirements.
Fault code 01 Fan fault Replace the fan.
Fault code 06/58 Output abnormal (Inverter voltage below than 190Vac or is higher than 260Vac) 1. Reduce the connected load.
2. Return to repair center
Fault code 08/09/53/57 Internal components failed. Return to repair center.
Fault code 51 Over current or surge. Restart the unit, if the error happens again, please return to repair center.
Fault code 52 Bus voltage is too low.
Fault code 55 Output voltage is unbalanced.

9 Appendix: Approximate Back-up Time Table

3.5KW

Load (W) Backup Time @ 24Vdc 100Ah (min) Backup Time @ 24Vdc 200Ah (min)
300 449 1100
600 222 525
900 124 303
1200 95 227
1500 68 164
1800 56 126
2100 48 108
2400 35 94
2700 31 74
3200 28 67

5.5KW

Load (W) Backup Time @ 48Vdc 100Ah (min) Backup Time @ 48Vdc 200Ah (min)
500 613 1288
1000 268 613
1500 158 402
2000 111 271
2500 90 215
3200 76 182
3500 65 141
4000 50 112
4500 44 100
5000 40 90

Note: Backup time depends on the quality of the battery, age of battery and type of battery. Specifications of batteries may vary depending on different manufacturers.

Model Number: 327-100015-02G

Models: 327-100015-02G, 3.5KW Plus Inverter MPPT SCC AC Charger, Inverter MPPT SCC AC Charger, MPPT SCC AC Charger, SCC AC Charger

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