One-click charging and discharging status:
Charging results:
Discharge results:
Information
Device Serial Number: Alias: Safety Standard: Grid code information Grid code information Upgrade
Data Logger: Property:
Command
When the setting fails, the machine is online. Please check the firmware version of the machine.
When the hybrid storage machine works in Grid-first mode, the MPPT energy will give priority to the load power on the largest grid side. The user can choose to work in this mode during periods of high electricity bills. The user needs to set the on and off time of the mode, and The end time of the battery SOC can be set by the user to be lower than or equal to the maximum output power of the battery.
Discharge Power Rate Discharge Power Rate Is Equal To The Actual Maximum Discharge Power Divided By The Theoretical Maximum Discharge Power Of The Battery. Sph Will Control The Actual Discharge Power Rate Not Higher Than The Set Value %
Discharge Stopped Soc The Battery Will Stop Discharge When It Reach The Setted Discharge Stopped Soc %
Time Period 1 :~:
Time Period 2 :~:
Time Period 3 :~:
When the hybrid storage machine works in Grid-first mode, the MPPT energy will give priority to the load power on the largest grid side. The user can choose to work in this mode during periods of high electricity bills. The user needs to set the on and off time of the mode, and The end time of the battery SOC can be set by the user to be lower than or equal to the maximum output power of the battery.
Time Period 4 :~:
Time Period 5 :~:
Time Period 6 :~:
When Sph Working In This Mode, Battery Would Be Charged First, It'S Suitable Working On The Period.When The Electric Charge Is Low. User Need To Set The Mode On And Off Time, And The End Time Of Battery Soc. Usercan Set Power Rate Which Less Than The Battery Maximum Output Power. If The Customer Don’T Enable The Ac Chg(Ac Grid Charging Function). Inverter Will Charge Battery By Pv Power As Large As It Can Do. If The Customer Enable The Ac Chg (Ac Grid Charging Function). Inverter Will Charge Battery By Pv Power And Ac Power From Grid As Large As It Can Do
Charge Power Rate Charge Power Rate Is Equal To The Actual Maximum Charge Power Divided By The Theoretical Maximum Charge Power Of The Battery, Sph Will Control The Actual Charge Power Rate Not Higher Than The Set Value %
Charge Stopped Soc The Battery will be stopped charged when it reach the setted charge stopped SOC %
Ac Charge Sph Can Charge Battery By Ac Power From Gridd
Time Period 1 :~:
Time Period 2 :~:
Time Period 3 :~:
When Sph Working In This Mode, Battery Would Be Charged First, It'S Suitable Working On The Period.When The Electric Charge Is Low. User Need To Set The Mode On And Off Time, And The End Time Of Battery Soc. Usercan Set Power Rate Which Less Than The Battery Maximum Output Power. If The Customer Don’T Enable The Ac Chg(Ac Grid Charging Function). Inverter Will Charge Battery By Pv Power As Large As It Can Do. If The Customer Enable The Ac Chg (Ac Grid Charging Function). Inverter Will Charge Battery By Pv Power And Ac Power From Grid As Large As It Can Do
Time Period 4 :~:
Time Period 5 :~:
Time Period 6 :~:
When The Hybrid Inverter Operates In The Load Priority Mode, The Hybrid Inverter Controls The Battery To Charge And Discharge According To The Amount Of Power That Is Fed Back To The Grid And Taken From The Grid. When There Is Electricity To Be Fed Back To The Grid, The Hybrid Inverter Adjusts This Part Of The Electricity To Charge The Battery, Reducing The Power Supply Back To The Grid; When There Is Power From The Grid, The Hybrid Inverter Regulates The Battery Discharge And Reduces The Power Consumption From The Grid. . When The Hybrid Inverter Operates In The Load Priority Prohibition Mode,The Hybrid Inverter Does Not Respond To Changes In The Amount Of Power Fed Back To The Grid And From The Grid, Maintaining Battery Power And Entering Other Priority Modes.
Discharge Stopped Soc When The Battery Power Reaches The Set Discharge Stop Soc, The Battery Will Stop Discharging. %
LF1 (5000~5995)
LF1 Time (1000~49950)
LF2 (5000~5700)
LF2 Time (0~2)
new_high_frequency (6010~6600)
HF1 Time (1000~49950)
HF2 (6200~6600)
HF2 Time (0~2)
HV1 (1050~1200)
HV1 Time (46~600)
HV2 (1050~1250)
HV2 Time (0~2)
LV1 (850~900)
LV1 Time (950~1000)
LV2 (650~750)
LV2 Time (500~1000)
LV3 (450~550)
LV3 Time (0~50)
%
%
Q (V) cut into low Voltage
Q (V) cut out low Voltage
Q (V) cut out high Voltage
Q (V) cut into high Voltage
Reactive power limit value (0~100)
Q1 Reactive Power Setting (0~100)
Q2 Reactive Power Setting (0~100)
Q3 Reactive Power Setting (0~100)
Q4 Reactive Power Setting (0~100)
Q(V) Cut Into Low Voltage Power Percentage %
Q(V) Cut Out High Voltage Power Percentage %
V
V
0 : no power Feed,100% : 100% Feed
Limit Power Rate(%)
(-0.8 ~ -1/0.8~1)
A (1~25A)
V (12.0~15.0V)
V (10.0~12.0V)
(0~3000ms)
(0~1000)
After activation, no power will be fed to the grid and loads. After the battery is fully charged to 100% with solar energy, it will no longer be discharged. Then the photovoltaic power generation will be limited and no power will be fed to the grid and loads. This can be set with one button until the function is canceled.
(10%~100%)
Enable winter mode
Winter mode time period
Winter mode On-grid discharge stop SOC % (10~30)
Winter mode Off-grid discharge stop SOC % (10~30)
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One-click charging and discharging
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Value
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Information
Device Serial Number: Software Version:
Rated Power: Device Model:
Model Austrian Safety Regulation:A1SE Country / Regionnull
Command

Note: When setting parameters, only the parameters under the selected button will be set.

Undervoltage U<(V) Range value:[10.0~440.0); Undervoltage Time U<(ms) Range value:[20~1000000);
Range value:[20~1000000);
Overvoltage U>(V) Range value:[10.0~440.0); Overvoltage Time U>(ms) Range value:[20~1000000);
Range value:[20~1000000);
Underfrequency f<(Hz)

If grid frequency is 50Hz ,[45.00~50.00);

If grid frequency is 60Hz ,[50.00~60.00);

 		Underfrequency Time f<(ms) Range value:[20~1000000);
Range value:[20~1000000);
Overfrequency f>(Hz)

If grid frequency is 50Hz ,(50.00~55.00];

If grid frequency is 60Hz ,(60.00~66.00];

If grid frequency is 50Hz ,(50.00~55.00];

If grid frequency is 60Hz ,(60.00~66.00];

 		Overfrequency Time f>(ms) Range value:[20~1000000);
Range value:[20~1000000);
Undervoltage U<<(V) Range value:[10.0~440.0); Undervoltage Time U<<(ms) Range value:[20~1000000);
Range value:[20~1000000);
Overvoltage U>>(V) Range value:[10.0~440.0); Overvoltage Time U>>(ms) Range value:[20~1000000);
Range value:[20~1000000);
Underfrequency f<<(Hz)

If grid frequency is 50Hz ,[45.00~50.00);

If grid frequency is 60Hz ,[50.00~60.00);

 		Underfrequency Time f<<(ms) Range value:[20~1000000);
Range value:[20~1000000);
Overfrequency f>>(Hz)

If grid frequency is 50Hz ,(50.00~55.00];

If grid frequency is 60Hz ,(60.00~66.00];

If grid frequency is 50Hz ,(50.00~55.00];

If grid frequency is 60Hz ,(60.00~66.00];

 		Overfrequency Time f>>(ms) Range value:[20~1000000);
Range value:[20~1000000);
Overvoltage 10min Average (V) Range value:[10.0~440.0); Overvoltage 10min Time (S) Range value:[0~1200 ];
Restart Slope_En
Start time (s) Range value:[0~1200 ]; Restart loadspeed (1%Pn/min) Range value:[0~6000 ];
Connect Vac High(V) Range value:[10.0~440.0); Connect Vac Low(V) Range value:[10.0~440.0);
Connect Fac Low(Hz)

If grid frequency is 50Hz ,[45.00~50.00);

If grid frequency is 60Hz ,[50.00~60.00);

 		Connect Fac High(Hz)

If grid frequency is 50Hz ,(50.00~55.00];

If grid frequency is 60Hz ,(60.00~66.00];

If grid frequency is 50Hz ,(50.00~55.00];

If grid frequency is 60Hz ,(60.00~66.00];
Restart time (s) Range value:[0~1200 ];
LFSM-O_En
Over Frequency Derating Start Point(Hz) Range value:[0~66.00);
Over Frequency Derating Rate(%Pref/Hz) Range value:[0~255 ]; Derating Stop Point(f)(Hz) Range value:[0~66.00);
Derating Recover Point(f)(Hz) Range value:[0~66.00);
P(U)_En
P(U) Start Point(V) Range value:[10.0~440.0);
P(U) Stop Point(V) Range value:[10.0~440.0); P(U)Stop Point Power Rate Range value:[0~100.0];

Active Power(% of Normal Apparent Power) 100%Pn W
Time Constants (s) Range value:[0~5000 ];
LFSM-U_En
LFSM-U Start point(Hz)

If grid frequency is 50Hz ,[45.00~50.00];

If grid frequency is 60Hz ,[55.00~60.00];
LFSM-U Gradient (%Pn/Hz) Range value:[0.0~300.0 ];
VFRT_En
Zero Current Point 1(V) Range value:[10.0~440.0);
Zero Current Point 2(V) Range value:[10.0~440.0); LVRT Start Point(V) Range value:[10.0~440.0);
Active Power Mode
Percentage of active power(%Pn) Range value:[0~100 ];
Exportlimit Enable
Export Limitation Power(%Pn) Range value:[-100.0~100.0];
DRMS/RRCR En If the active power has already been controlled by an external device (RRCR), the active power percentage will automatically respond to the external control and cannot be manually set again.
Reative Power Mode
Power factor Range value:[-1~1 ];

eg.+0.8 Leading,-0.8 Lagging
Standard PF Characterateristic Curve
50%Pn Power Factor
1
 100%Pn Power Factor
0.9
Q(U) Mode
Time Constants (s) Range value:[0~200 ];
Q(U) Point 1(V) Range value:[10.0~440.0); Qmax(%) Range value:[0~100.0];

Reative Power (% of Normal Apparent Power) -0% Pn var

cosphi.min: 0.4
Q(U) Point 2(V) Range value:[10.0~440.0);

Reative Power (% of Normal Apparent Power) -0% Pn var
Q(U) Point 4(V) Range value:[10.0~440.0);

Reative Power (% of Normal Apparent Power) -0% Pn var
Qmax point1(inductive)(%) Range value:[0~1000];
Qmax point4(capacitive)(%) Range value:[0~1000];
Q(U) Point 3(V) Range value:[10.0~440.0);

Reative Power (% of Normal Apparent Power) -0% Pn var
Percentage of reactive power(%) Range value:[-100~100 ];
Backup En