SUNGOLDPOWER SGC481585A MPPT Solar Charge Controller User Manual
- June 17, 2024
- sungoldpower
Table of Contents
- SGC481585A MPPT Solar Charge Controller
- Introduction to Product
- Technical Parameter
- State instruction for indicator light
- Key
- Parameter Setting and Special Function Use
- Liquid Crystal Display
- Product Installation
- Protection Function
- System Maintenance
- Product Dimension
- References
- Read User Manual Online (PDF format)
- Download This Manual (PDF format)
Sun Gold Power Co.,Ltd
www.sungoldpower.com
MPPT Solar Charge Controller
SGC481585A/SGC4815100A/SGC482585A/SGC4825100A
User Manual
Version: 1.03
Any change shall not be otherwise notified.
SGC481585A MPPT Solar Charge Controller
Dear Users:
Thank you for choosing our products!
Safety Instruction
- The applicable voltage of the controller is beyond safety voltage of personnel. Before operation, please read the instruction manual carefully and start operating only after receiving safe operation training.
- There is no parts requiring repair or maintenance within the controller, so please don’t disassemble or repair the controller without authorization.
- Please install the controller indoors and prevent water against entering into the controller.
- Please install the controller in a well-ventilated place and the cooling fans in operation have high temperature.
- It is suggested to install a suitable fuse or breaker outside of the controller.
- Before installing and adjust the controller wiring, please break the connecting wire of the solar panel battery and the fuse or breaker close to the battery terminal.
- After installation, inspect whether all wires are connected firmly to avoid any hazard caused by accumulated heat owing to poor contact.
Warning:
Indicating that the operation is hazardous, please fully prepared for safety
before operation.
Notice:
Indicating that the operation is destructive.
Tips:
Our main sales MPPT controller product model is SGC4825100A, please note the
content of the parameters in the user manual when you use.
Introduction to Product
1.1 Product Overview
The controller adopts the leading PowerCatcher maximal power Tracking
technology in the industry to achieve maximal energy Tracking for solar panel,
so that it can quickly and accurately trace the maximal power point of the
solar battery, acquire the maximal energy of the solar panel and
significantly improve the energy utilization ratio of the solar system. Widely
applied to solar off-line photovoltaic system for managing solar panel and
storage battery in operation, the controller is the core control component of
off-line photovoltaic system.
The inside of the controller possesses sound electronic failure detecting and
protection function to avoid the product component damage caused by
installation error and system failure.
The controller is equipped with an LCD display screen to simultaneously
support data interaction, setting and other operations with mobile phone APP,
PC upper computer and other devices.
1.2 Product Characteristics
- PowerCatcher maximal power Tracking technology can still trace the maximal power point of solar battery in the complicated environment. Compared with traditional MPPT Tracking technology, it enjoys higher response speed and higher Tracking efficiency.
- MPPT charge efficiency is greater than traditional PWM charge efficiency by about 15% ~20%.
- MPPT Tracking efficiency can be as much as 99.9%.
- Adopting advanced digital power technology, the circuit energy conversion efficiency can be as much as 98%.
- The products support lithium batteries, charging output has active voltage stabilization function. In case of open circuit of lithium batteries or BMS overcharging protection, the storage battery end of the controller shall output stable target voltages in time, thereby possessing good lithium electric activation function.
- Preset a variety of battery types: lithium batteries, sealed batteries, colloidal batteries, open batteries and selfdefinition.
- Lead-acid batteries support temperature compensation function.
- With charging line loss compensation, the voltage of the battery terminal can be accurately controlled.
- With current-limiting charging, in case of too much battery panel power (charging current is greater than rated current), the controller automatically reduces the charging power so that it can operate within the rated charging current.
- With built-in overtemperature protection mechanism, when the temperature exceeds the set temperature value, the charging power shall decline in a linear way with the temperature.
- It supports parallel function and breaks through the power limit of single unit. Therefore, combination of several units can meet greater charging power.
- With built-in bluetooth 4.0BLE module, it can achieve mobilephone APP data interaction.
- Supporting standard Modbus protocol, it provides protocol technology support to facilitate secondary development and application by users.
- Programmable relay output
1.3 Description of Appearance and Interface
No. | Name | No. | Name |
---|---|---|---|
① | Liquid crystal display (LCD) | ⑦ | RS485 communication interface |
② | Bluetooth 4.0BLE module | ⑧ | Key |
③ | Positive interface of battery | ⑨ | TTL communication interface |
④ | Negative interface of battery | ⑩ | Battery temperature sampling interface |
⑤ | Negative interface of solar panel | ⑪ | Battery voltage sampling interface |
⑥ | Positive interface of solar panel | ⑫ | Relay output interface |
Note: Negative poles of storage battery and solar battery are a common negative pole design.
1.4 System Wiring Schematic Diagram
1.5 Introduction to Maximal Power Tracking Technology
Maximal power point tracing system is an advanced charge technology where the
operation state of the electric module is adjusted so that the solar battery
can output more electric energy. Owing to the nonlinear characteristics of
solar battery array, there is an array of maximal energy output point
(maximal power point), the traditional controller (on-off charging technology
and PWM charging technology) cannot maintain storage battery charging at this
point. Therefore, it is unable acquire the maximal energy of battery panel.
However, the solar controller with MPPT control technology can trace the
maximal power point of the array to acquire the maximal energy to charge the
storage battery.
Taking 12V system as the example, the peak voltage (Vpp) of solar battery is
about 17V, but the storage battery voltage is about 12V, when general charge
controller is charging, the voltage of the solar battery is about 12V, the
maximal power is not fully exerted. MPPT controller can overcome the problem
and adjust the input voltage and current of the battery panel from time to
time so that the input power can be the maximal value.
Comparing with traditional PWM controller, MPPT controller can exert the
maximal power of solar battery.
Therefore, bigger charge current can be provided. Generally speaking, compared
with PWM controller, MPPT can improve energy utilization ratio by 15%~20%.
Owing to different ambient temperature and illumination conditions, maximal power point can change frequently. Our MPPT controller can adjust parameters according to different conditions so that the system can be close to the maximal operation points at any time. The whole process is completed fully automatically without any adjustment by users.
1.6 Introduction to Charging Stage (MPPT, Constant Voltage and Current)
1.6.1 Charging process of lead-acid battery
As one of the charging processes of lead-acid batteries, MPPT usually needs to
be combined with equalizing charge/lifting charge, floating charging and other
charging methods to jointly complete the charging management for storage
batteries.
The charging stages of lead-acid batteries include MPPT charging, constant
voltage charging (equalizing/lifting/floating charging) and current limiting
charging.
a) MPPT charge
In MPPT charging stage, the battery voltage has not reached the target
constant voltage value, so the controller will perform MPPT charging to
maximize the charge amount from solar energy quantity to the storage battery.
After the storage battery voltage reaches the constant voltage value, it shall
automatically change to constant voltage charging.
b) Constant voltage charge
When the storage voltage reaches the target constant voltage value, the
controller shall exit from MPPT charging and enter into constant voltage
charging. With the progress of constant voltage charging, charging current
shall drop gradually with time lapse. Constant voltage charging is divided
into two stages, namely equalizing charge and lifting charge respectively.
These two charging process shall not repeated (the equalizing charge interval
is 30 days at a time by default).
c) Equalizing charge
Warning: Explosion Risk!
Equalizing open-head lead-acid batteries can produce explosive gases and
battery compartments must be well ventilated.
Note: Device Damage!
Equalizing may increase battery voltage, but damage the level of sensitive DC
load. Therefore, it is necessary to validate that the allowable input voltage
of all loads is greater than the set equalizing charge value.
Note: Device Damage!
Excessive charging and gas evolution may damage polar board of storage and
result in peeling of active substances on the battery plate. Too high
equalizing charge voltage or too long charging time may damage batteries.
Please set related parameters according to the specification requirements of
the batteries used in the system.
Some types of batteries benefit from periodic equalizing charge, which mainly
increases the charging voltage of batteries so that it is higher than the
standard supply voltage. Equalizing charge can gasify the battery electrolyte,
balance the battery voltage and complete the chemical reaction. Equalizing
charge and lifting charge are not repeated in a charging process to avoid too
much precipitated gas or overheated battery.
Lifting charge
Generally, it is considered that the lifting charge stage lasts for 2h by
default. When the duration reaches the set value, the system shall turn to the
floating charge (lifting charge duration: only the self-defined battery type
can be changed).
Floating charge
Floating charge is the last stage for constant voltage of lead-acid storage.
The controller keeps the charging voltage at the floating charge voltage. At
this stage, weak current charge is performed for the battery at this stage to
guarantee that the battery maintains at the full charging state.
At floating charge stage, when the battery voltage drops to the lifting charge
return voltage, after a period of time, the system shall exit from the
floating charge stage and then enter into MPPT charge stage again.
1.5.21.5.2 Charging Process of Lithium Battery/Customized Lithium Battery
The charging stages of lithium batteries contain MPPT charging, constant
voltage charging, and current-limiting charging
a) MPPT charging
In MPPT charging stage, the battery voltage has not yet reached the target
constant voltage.
The controller will perform MPPT charging to maximize the charge amount from
solar energy quantity to the storage battery. After the storage battery
voltage reaches the constant voltage value, it shall automatically change to
b) constant voltage charging.
b) Constant Voltage Charging
Lifting charge is the unique constant voltage charge state. Therefore, only
when the storage voltage drops to the set value for lifting and recovering
charge, the system can exit from the constant voltage charging stage and then
enter into MPPT charging stage again.
1.5.3 Current-limiting charge over rated current
Current-limiting charge runs through the whole charging cycle. In any charging
stage, as long as it is detected that the current is beyond the rated current,
it shall enter into the current-limiting charge automatically and the charging
current is limited to the rated current.
1.5.4 Overtemperature and Current-Limiting Charge of Device
Overtemperature and current-limiting charge of device runs through the whole
charging cycle. In any charging stage, as long as overtemperature of device is
detected, it will automatically enter into linear current-limiting charge.
Technical Parameter
2.1 Electrical parameter
Name of Parameter | P arameter Value |
---|---|
Type | SGC481585A |
System Voltage | 12V/24V/36V/48V |
No-load loss | 0.54W |
Battery voltage | 9V~64V |
MaximumPVopen-circuitvoltage | 150V |
Maximum PV input current | 70A |
MaximumPVshort-circuitcurrent | 70A |
Maximum voltage range at power point | Battery voltage +2~120V |
+2~180V
Rated charging current| 85A| 100A| 85A| 100A
Settable charging current| 0-85A| 0-100A| 0-85A| 0-100A
Maximum output overcurrent protection| 85A| 100A| 85A| 100A
Maximum output power| 4400W| 5280W| 4400W| 5280W
Power of solar panel (12V)| 1100W| 1320W| 1100W| 1320W
Power of solar panel (24V)| 2200W| 2640W| 2200W| 2640W
Power of solar panel (36V)| 3300W| 3960W| 3300W| 3960W
Power of solar panel (48V)| 4400W| 5280W| 4400W| 5280W
Charging conversion efficiency| ≤98%
MPPT tracing efficiency| >99%
Temperature compensation coefficient| -3mV/℃/2V (default, settable lead-acid);
no temperature compensation for lithium battery.
Communication way| TTL/Isolated RS485; baud rate 9600, digital bit 3, stop bit
1, no check bit
Bluetooth| Built-in bluetooth 4.0BLE module, achieving mobilephone APP
monitoring
Internal temperature protection| When interior temperature of controller is
higher than the set value, it shall perform linear power reduction operation
External temperature sampling of battery| The temperature is used for battery
temperature compensation and battery temperature protection
Programmable relay| DPST 10A/250VAC;10A/30VDC
Protection function| Battery overcharging protection, battery over discharge
protection, PV anti-reverse protection, reverse charge protection at night,
interior overtemperature protection of controller and over-current protection
in charge
Operation temperature| -35℃ ~ +65℃(No derating within 40 ℃)
Degraded ambient temperature| 40 ℃
Elevation| ≤3000m
Protection grade| IP32
Weight| 5.7kg
Product size| Conventional:314227121mm
MC4:314259121mm
2.2 Battery Type Parameter by Default
P arameter Contrast of Different Types of Battery
| Sealed lead-acid battery| Colloidal lead-acid battery| Open-
head lead-acid battery| Lithium battery| Self-defined User
(12V by default)
Overvoltage breaking voltage| 16.0V| 16.0V| 16.0V| 16.0V| 9~17V
Equalizing voltage| 14.6V| ——| 14.8V| ——| 9~17V
Lifting voltage| 14.4V| 14.2V| 14.6V| 14.4V| 9~17V
Floating voltage| 13.8V| 13.8V| 13.8V| ——| 9~17V
Lifting recovery voltage| 13.2V| 13.2V| 13.2V| 13.2V| 9~17V
Overdischarge recovery voltage| 12.6V| 12.6V| 12.6V| 12.6V| 9~17V
Undervoltage alarm| 12.0V| 12.0V| 12.0V| 12.0V| 9~17V
Overdischarge voltage| 11.1V| 11.1V| 11.1V| 11.1V| 9~17V
Overdischarge cutoff| 10.6V| 10.6V| 10.6V| 10.6V| 9~17V
Overdischarge delay| 6S| 6S| 6S| 6S| 1-30S
Equalizing charge interval| 30days| 0days| 30days| ——| 0~250days
(0 indicate closing and equalizing charge function)
Equalizing duration| 120 minutes| ——| 120 minutes| ——| 10~600 minutes
Lifting duration| 120 minutes| 120 minutes| 120 minutes| ——| 10~600 minutes
Temperature compensation mV/℃/2V| -3| -3| -3| ——| Automatic removing
temperature compensation for lithium
State instruction for indicator light
3.1 Charge state indication
No. | S tate of Indicator Light | Charge State |
---|---|---|
① | Normal on | MPPT Charge |
② | Slow flash (on 1s, off 1s, period 2s) | Lifting charge |
③ | Single flash (on 0.1s, off 1.9s, period 2s) | Floating charge |
④ | Quick flash (on 0.1s, off 0.1s, period 0.2s) | Equalizing charge |
⑤ | Double flash (on 0.1s, off 0.1s, on once again 0.1s, off once again 1.7s, | |
period 2s) | Current limiting charge | |
⑥ | Off | No charge is started |
3.2 State Display of Battery
Color of Indica t o r Light| S tate of Indicator
Light| S tate of Battery
---|---|---
Green| Normal on| Full battery voltage
Yellow| Normal on| Normal battery voltage
Red| Normal on| Battery voltage is below the undervoltage point
Quick flash (on 0.1s, off 0.1s, period 0.2s)| Battery overvoltage or
overtemperature
3.3 Type Indication of Battery
Color of Indicator Light | T ype of Battery |
---|---|
Red | Open-head lead acid battery FLD |
Yellow | Colloidal lead acid battery GEL |
Green | Sealed lead acid battery SLD |
Blue | 12V lithium battery LI (lithium iron phosphate by default) |
Purple | 24V lithium battery LI (lithium iron phosphate by default) |
Orange | 36V lithium battery LI (lithium iron phosphate by default) |
Cyan | 48V lithium battery LI (lithium iron phosphate by default) |
White | Self-defined USE (12V sealed lead acid by default) |
Key
4.1 Key function I: set battery type
Press the key for 8s and the battery type indicator light starts flickering
(the controller can turn off the charge at this time). At this time, after
each press, the battery type indicator light turns to another color and there
is a corresponding battery type. After the battery type is selected, press
the key for 8s once again or 15s after no operation, the controller shall
automatically save the battery type set at present and exit from the setting
mode and enter into the normal operation mode; (LCD is the standard
configuration. Generally, this method is not used for setting).
4.2 Key function II: recover factory default parameter
Press the key for 20s and the red indicator light of the three ones on the
controller flickers and the controller is restored to the factory default
parameters.
Parameter Setting and Special Function Use
5.1 Monitoring Use of Mobile Phone APP (Standard Configuration)
Blue tooth 4.0BLE module is integrated in the controller and users can use the
mobile phone APP developed by our corporation to achieve data monitoring,
setting and other operations to the controller.
Please contact business personnel to get related software and operation
instruction.
5.2 Application of Lead Acid Battery
- The LCD screen on the controller (see 6.3 set system parameters via the LCD screen) or mobile phone APP can be used to select the battery type matched with the battery. The changed system voltage can be effective only upon restart.
- If the preset lead-acid battery parameters are not suitable for the battery used by users and users can use customization. All parameters customized can be set only through communication, such as mobile phone APP, PC client software, or perform communication setting via other user system in accordance with communication protocol and controller.
(At delivery: the self-defined default values are same as the sealed lead acid battery parameters. The system voltage is 12V)
5.3 Application of Lithium Battery
Preset LI for controller containing lithium iron phosphate of specifications
12V/24V/36V/48V. If the preset values for the lithium battery are not suitable
for users, you can perform communication setting with the controller via
mobile phone APP, LCD screen of the device, external LCD screen and other
systems according to the communication protocol through other systems of the
user.
Customization may be lead-acid batteries or lithium batteries. To apply
lithium batteries in the self-defined battery type, it is required to meet the
following conditions:
- Set a fixed voltage for the system voltage, one of 12V/24V/36V/48V.
- Equalizing charging time interval is set as 0;
- Equalizing charging time is set as 0;
- Temperature compensation is set as 0.
Meeting the above four conditions, the system automatically identifies the
batteries as lithium batteries.
Therefore, the system possesses lithium battery activation, charging and other
charge control logic.
5.4 Setting of Charging Current
The rated current of the controller is 100A, which supports the setting of
communication instructions, ranging from 0.00 A to 100.00A. Via mobile phone
APP or the user system provided by our company, communication setting is
performed for specified register E001H with the controller via the mobile
phone APP or the user system according to the protocol. Please refer to our
Modbus protocol for setting and analysis.
5.3 Application of Lithium Battery
Preset LI for controller containing lithium iron phosphate of specifications
12V/24V/36V/48V. If the preset values for the lithium battery are not suitable
for users, you can perform communication setting with the controller via
mobile phone APP, LCD screen of the device, external LCD screen and other
systems according to the communication protocol through other systems of the
user.
Customization may be lead-acid batteries or lithium batteries. To apply
lithium batteries in the self-defined battery type, it is required to meet the
following conditions:
- Set a fixed voltage for the system voltage, one of 12V/24V/36V/48V.
- Equalizing charging time interval is set as 0;
- Equalizing charging time is set as 0;
- Temperature compensation is set as 0.
Meeting the above four conditions, the system automatically identifies the
batteries as lithium batteries.
Therefore, the system possesses lithium battery activation, charging and other
charge control logic.
5.4 Setting of Charging Current
The rated current of the controller is 100A, which supports the setting of
communication instructions, ranging from 0.00 A to 100.00A. Via mobile phone
APP or the user system provided by our company, communication setting is
performed for specified register E001H with the controller via the mobile
phone APP or the user system according to the protocol. Please refer to our
Modbus protocol for setting and analysis.
No. | Definition | No. | Definition |
---|---|---|---|
① | NC | ⑤ | Isolate power ground |
② | NC | ⑥ | D- |
③ | Remote on/off of charger | ⑦ | D+ |
④ | Remote on/off of charger | ⑧ | Isolate positive power supply |
5.6 TTL Communication
Users can utilize Modbus protocol to perform data monitoring, parameter
setting and other operations for the controller via the port.
No. | Definition |
---|---|
① | Controller supplies +12.8V outwards. |
② | Data receiving terminal RX of controller |
③ | Data sending terminal TX of controller |
④ | GND |
5.7 Temperature Sampling of Battery
Not connected to temperature sensor, it is 25℃ by default; After the
temperature sensor is connected, high and low temperature protection is
performed or charging temperature compensation is performed for the battery
(there is no temperature compensation for lithium battery).
Wiring method: the wiring terminal of the temperature sensor is connected to
(9) and the temperature sensor is fixed thereon.
5.8 Voltage Compensation Wire of Battery
Owing to the configuration, the charging power is great and the diameter of
wire from battery to the controller is small. Therefore, the voltage collected
by the controller terminal is greater than the practical voltage of the
battery terminal and the battery cannot be fully charged. In certain degree,
the voltage of the battery terminal can be more accurately collected via the
voltage sampling wire of the battery and the voltage difference can be output
in a compensated way, so that the battery terminal can get more reasonable
charging voltage.
The positive and negative poles of the battery are respectively connected to
the positive and negative poles of the battery voltage sampling terminal (10)
via the voltage compensation wire. Please note that the left is the positive
terminal and the right is the negative terminal.
The wiring way is shown in the figure below:
5.9 Programmable Relay Output
- Single-pole double-throw (DPST) relay
- Relay contact specification 250VAC/10A, 30VDC/10A
- From left to right, there are NC contacts, common points and NO contacts.
Relay triggering condition:
-
When battery voltage is normal,the relay coil doesn’t operate in NC state
(C and NC are conducted) -
In case of overvoltage or over discharge of the battery, relay coil operates in NO state (C and NO are conducted)
5.10 Use of Parallel Operation Function
5.10.1 Parallel operation function:
Parallel operation function means that several controllers charge one battery
pack one to one uniformly. Each controller has one independent solar panel;
these controllers are connected via RS485 communication wires and the host
system uniformly synchronizes the charge state stage, constant voltage value
and other parameters to the slave.
In this way, the device can break through the power limit of single device. In
addition, parallel operation of several devices can meet greater charging
power demands.
5.10.2 Parallel operation step:
- RS485 communication ports of each controller are set as parallel operation function
The device is only designed with a 485 communication. Therefore, parallel operation function is required and it is necessary to set RS485 communication function as the parallel operation function (for related protocol data, please refer to our Modbus protocol) PDU Operation Address| Data| Function
---|---|---
E327H| 0000H| RS485 communication interface is taken as communication function (default)
E327H| 0001H| RS485 communication interface is used as parallel operation function - The device addresses of each controller are set as 1, 2, 3, 4….. according to the sequence.
- D+ of different RS485 communication wires are connected together and D- are connected together in parallel.
- Afterwards, power is supplied to these controllers.
Note:
- Host and slave are decided and changed by software algorithm, namely host and slave identifications are not determined.
- As long as it is not the time when the host sends the synchronizing information, operation to E327H is effective.
- The parallel operation function can also send and receive data within certain time of period. However, if data receiving and sending is at the time when the host sends synchronizing data to 485 bus, there maybe communication data conflict error!!!
- The controller unit can automatically identify the host and the host shall regularly send the synchronizing information to RS485 bus. The slave receives the information for implementation.
- During parallel operation process, once the host fails to perform charging or doesn’t perform charging, the slave meets the charge. After a period of time, the slave shall generate new host to further manage the charge.
At this time, previous host becomes a slave.
Liquid Crystal Display
LCD module as the standard configuration of the controller can be installed on the controller surface or in other places via DB9 extension wire in accordance with practical conditions.
6.1 Menu Schematic Diagram
6.2 Menu Browse
6.3 Set System Parameter via LCD
Setting method:
-
Under any menu, press key “ENTER” for long time to enter into “Parameter Setting” menu:
(1) Press key “ENTER” for short time and adjust the parameter value;
(2) Press key “SELECT” for short time and select setting item;
(3) Press key “ENTER” for 2 seconds, save and exit from setting mode;
(4) Select “FLD/GEL/SLD/LI” battery type and press key “SELECT” to only perform switching between “system voltage” and “battery type”.
(5) After selecting “USE” for customizing battery type, press key “SELECT” for switchover among “system voltage /equalizing charging voltage/lifting charging voltage/floating voltage/over discharge return voltage/over discharge voltage”.
Note:
(1) The changed “system voltage” can be effective only after poweron again.
(2) Users must be careful while customizing parameters. The system may not operate normally owing to inaccurate parameter! -
Customized USE menu
No.| Liquid Crystal Display| Set Item| P arameter
Range| R emark
---|---|---|---|---
1| USE| Battery type| —| Customizing battery type
2| 12V/24/36V/48V| System voltage| 12V/24/36V/48V| “12V/24/36V/48V”
simultaneous on indicates automatic identification
3| EQUALIZE| Equalizing charging voltage (USE)| 9.0~17.0V| —
4| BOOST| Lifting charging voltage (USE)| 9.0~17.0V| —
5| FLOAT| Floating charging voltage (USE)| 9.0~17.0V| —
6| | Over discharge recovery voltage (USE)| 9.0~17.0V| —
7| | Over discharge voltage (USE)| 9.0~17.0V| —
6.4 Abnormal Code Display
No.| Error Code Displayed by LCD| Note| Implementation
Result
---|---|---|---
1| E0| No abnormity| Normal system
2| E1| Battery over discharge| Battery voltage rises to over discharge return
voltage and over discharge prompt is released.
3| E2| Battery over voltage| No charging
4| E3| Under voltage alarm of battery| Battery voltage is lower than
undervoltage alarm threshold value, it is only prompted that the system is
normal.
7| E6| Interior over temperature of controller| Excessive internal temperature
of controller, MPPT controller starts linear power charge; it shall recover
automatically after reducing to certain value.
8| E7| Battery over temperature| Turn off the charging and then recover the
charging automatically after the voltage is lower than certain value.
9| E8| Excessive charge current of input power of solar panel| MPPT controller
is limited within rated current range
10| E10| Over voltage of solar panel| Over voltage of solar panel, turn off
the charging and recover the charging when the voltage is lower than the set
value.
12| E15| Battery not connected or feedback electricity of lithium battery| As
long as the solar panel voltage meets the charging condition, lithium battery
has constant voltage output, recover to normal after the battery is connected.
13| E16| Over temperature of battery| No charging
15| E18| BMS over charge protection| No charging
16| E19| Low temperature of battery| No charging
6.5 Common Problem and Treatment Method
Phenomenon | T reatment Method |
---|---|
Indicator light or LCD is not on | Please check whether battery and solar panel |
are correctly connected.
No datum on LCD| Poor communication; check the communication wire.
There is voltage on the solar panel, no voltage output at battery end, display
code E1| No battery can be detected at the lead-acid battery terminal. There
is no voltage output from both ends of the battery. It shall return to normal
state after battery is connected.
Connected with 12V/24V/36V/48V normal voltage battery and the battery icon on
the LCD flashes slowly, display error E1| Check whether it is set as
corresponding system voltage or automatic identification, restart the
controller;
After setting the system voltage, it is designed for safety and can be
effective only after restart.
Battery icon indicator light flashes quickly without charging. Display code
E1| Overvoltage of system; inspect the overvoltage reason of the battery. It
shall restore after reduction of voltage.
The device cannot be searched by mobile phone Bluetooth.| Inspect whether
other mobile phones are connected with the Bluetooth setting.
No charging by controller.| Inspect whether wires are correctly connected,
whether solar panel voltage exceeds the rated value, whether battery exceeds
the voltage, check LCD error code. Inspect whether there is interior
overtemperature, exterior overtemperature, low temperature of exterior
lithium, or whether the lead-acid battery is open, etc.
Other problem or insoluble abnormity| Try to restore the factory setting and
then set related parameters in accordance with system configuration. Take care
in the operation!
6.6 Installation Size of LCD
Product size:104.555.511.8mm
Installation size: 96*φ3.5mm
Product Installation
7.1 Installation Notice
◆ Please be careful in battery installation. To open the open-head lead-acid
battery, it is required to wear a pair of goggles. Once contacting the acid
liquid of the battery, please flush with clear water immediately.
◆ Avoid placing metal articles close to the battery to prevent short circuit
of battery.
◆ The battery in charging may generate acid gas, so please guarantee well-
ventilated ambient.
◆ The battery may generate flammable gas, please keep away from spark.
◆ Please avoid direct sunlight and rain water in outdoor installation.
◆ The virtually connected points and corrosive wires may generate heat and
melt the insulation layer of the electric wire, burn surrounding materials and
even cause fire. Therefore, it is required to guarantee that all connectors
are tightened. The electric wires shall be fixed with wire ties to avoid
connector looseness in mobile application.
◆ To connect the system, the voltage at the output terminal of the component
may exceed safe body voltage.
Therefore, it is required to use insulation tools in operation and guarantee
dry hands.
◆ The wiring terminal of the battery on the controller can be connected with
only one battery, or with a set of battery. In the manual, the instructions
are only for one battery. However, they are applicable to a set of batteries.
◆ Please observe the safe suggestion of the battery manufacturer.
◆ The system connecting wire is selected based on the current density no less
than 4A/mm2.
◆ The ground terminal of the controller shall be grounded.
◆ In installation, the battery shall not be reversely connected, which may
cause irreversible damage!
7.2 Wiring Specification
It is required to observe national and local electrical specification
requirements for wiring and installation ways.
PV and battery wiring specification must be selected based on rated current.
Please refer to the table below for the wire specification.
T ype| Maximal input current of PV| Maximal wire size at PV
terminal (mm 2 /AWG)| Rated charge current| Wire size of
battery
(mm 2 /AWG)
---|---|---|---|---
SGC481585A| 60A| 15/5| 85A| 21/4
SGC4815100A| 70A| 18/4| 100A| 25/2
SGC482585A| 60A| 15/5| 85A| 21/4
SGC4825100A| 70A| 18/4| 100A| 25/2
Earthing instructions: The screw hole at the side earthing mark of the radiator is earthing. If earthing is needed, the diameter of earthing wire shall not be less than 15/5(m㎡ /AWG)
7.3 Installation and Wiring
Warning:Explosion hazard! Never install the controller and open-head
battery into an enclosed space or in an enclosed room with possible gathering
of battery gas.
Warning:High voltage is hazardous! Photovoltaic array may generate high
open voltage.
Before wiring, please break the breaker or fuse. Please be careful during the
connection process.
Note:To install the controller, please guarantee that there is enough air
flowing through the cooling fin of the controller. At least leave 150mm space
above or below the controller so as to guarantee natural and convective heat
dissipation. If installed in an enclosed box, please guarantee reliable heat
dissipation via the box.
Step 1: select an installation place
It is prevented to install the controller to a place with direct sunlight,
high temperature and possible water inlet. In addition, it is required to
guarantee well ventilation around the controller.
Step 2: fix screw
Mark a sign at the installation position in accordance with the installation
size of the controller. Drill four installation holes with proper size at 4
marking positions. Afterwards, fix the screws to the upper two installation
holes.
Step 3: fix controller
Align the fixing hole of the controller with two screws fixed in advance, then
hang the controller and fix the lower two screws.
Step 4: Wiring
In order to guarantee safety in installation, we recommend a wiring sequence
for the main circuit; it is prohibited to connect the positive and negative
poles of the battery reversely!!!!!
Warning: :Danger of electric shock! We strongly recommend to connect the
fuse or breaker at the photovoltaic array and the battery terminals to prevent
electric shock hazard in wiring or inaccurate operation. Furthermore, before
wiring, it is required to guarantee that the fuse or breaker is in open
state.
Warning::Danger of high voltage! Photovoltaic array may generate high
open voltage. Before wiring, please open the breaker or fuse,
Warning:Danger of explosion! Short circuit of positive and negative
terminals of battery and wires connected to the positive and negative poles
may cause fire or explosion. Please take care in operation.
Please connect the battery at first and then the battery panel. Please observe
the connecting way of pole “+” before pole “-“.
When all power lines are connected firmly and reliably, inspect whether the
wires are correct once again and whether the positive and negative poles are
connected reversely. After it is confirmed that all are correct, connect the
battery fuse or breaker at first and then observe whether LED indicator light
is on. If the light is not on, please immediately cut the fuse or breaker, and
then inspect whether the wires are correctly connected.
If the battery is connected normally, connect the battery panel. If the
sunlight is sufficient, charging indicator light of the controller shall be
normally on or flickers, start charging the battery.
Note: install the battery fuse close to the battery terminal as far as
possible. It is suggested that the installation distance shall not exceed
150mm.
Protection Function
8.1 Introduction to Protection Function
-
Waterproof
Waterproof grade: IP32 -
Overtemperature protection inside device
When interior temperature of the controller is beyond the set value, the controller shall reduce the charging power or even break automatically in charging to further slow down temperature rise in the controller. -
Overtemperature protection of battery
To achieve overtemperature protection of battery, it is required to connect the temperature sampling sensor of battery externally. When it is detected that the battery temperature is high, stop charging. When the battery temperature is reduced to be lower than the set value by 5℃, charge shall be restored automatically after two seconds. -
Overpower protection for input
When the battery panel power is greater than the rated power, the controller shall limit the charge power within the rated power range to prevent controller damage caused by excessive current. At this time, the controller shall enter into the current limiting charge. -
Overvoltage of photovoltaic input terminal
In case of excessive voltage at photovoltaic array input terminal, the controller shall automatically cut the photovoltaic input. -
Reverse protection for photovoltaic input
When the photovoltaic array polarity is connected reversely, the controller shall not damage and shall further operate after wiring error is corrected. -
Anti-reverse charge protection at night
It is required to prevent the accumulator against discharge via solar battery.
Special notice: there is no reverse wiring protection function for battery.
System Maintenance
In order to guarantee that the controller can maintain the optimum operation
performance for long time, it is suggested to inspect following items
regularly.
◆ Confirm that air flow around the controller cannot be blocked and clear away
the dirt or sundries on the radiator.
◆ In case of abnormal failure or error prompt, adopt corrective measures in
time.
◆ Inspect whether there is corrosion, insulation damage, high temperature,
burning/discolor sign on the wiring terminal, whether the shell is deformed.
If any, perform repair or replacement in time.
◆ Any wire with exposure, damage, poor insulation performance shall be
repaired or replaced in time.
◆ Any dirt, nesting, insect or corrosive phenomenon shall be cleared in time.
Warning:Danger of electric shock! To carry out above operation, please
ensure that all power of the controller has been broken. Afterwards, perform
corresponding inspection and operation! Any nonprofessional shall not operate
without authorization.
Product Dimension
-
Common size:
-
-MC4 size:
Mode:108865
Sun Gold Power Co.,Ltd
www.sungoldpower.com