Sermatec 10kVA high-voltage hybrid inverter SMT-10K-TL-TH

Sermatec application . Parameterizable ONLY VIA ANDROID!
/!\ Updates to be carried out exclusively at WATTUNNEED's request .

It allows users to produce their own energy, and to obtain certain economic advantages.
When solar energy is sufficient, the inverter draws power from the PV station to supply consumers, and the remaining power will charge the batteries. The inverter automatically feeds the battery charge.
When the battery's energy is depleted, the inverter draws power from the grid, supplies the consumers and recharges the battery.
This on/off grid inverter can be installed indoors or outdoors.

One-touch setting

- Automatic matching
- Multi-language
- Self-diagnosis, maintenance-free

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Simple installation

- User manual and installation video
- Modular installation
- International standard cables

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Variety

- Compatible with various input sources
- Ufepo4 & lead-acid battery compatible
- Solar, grid and generator access
- On & Off-grid switching time less than 10 ms, can be used as UPS
- Single- and three-phase output for residential and commercial applications
- Flexible for adding/upgrading more inverters or battery systems.

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Efficiency

- 99% high efficiency
- Advanced tracking technology to improve PV station efficiency
- High-precision MPPT control algorithm and INV algorithm for high-efficiency grid connection and autonomous energy conversion.

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Safety

- Self-protection technology
- Wide voltage and frequency input
- IP65 protection
- Automatic air cooling
- Stable operation at altitude, at high temperatures and in very humid environments

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Intelligence

- Intelligent management system enforces self-operation
- WIFI, CAN, RS485, USB (optional), GPRS (optional) Multiple monitoring modes

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New from Sermatec: AC Coupling

Maximize self-consumption, even with older systems

The Sermatec hybrid inverter is connected in parallel to the grid inverter. Photovoltaic energy is first used to power loads, then to charge the battery, and any excess photovoltaic energy can be fed back into the grid.

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View daily and total consumption status

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You can view consumption from your system

There's an asymmetry between our electricity needs and the output of our solar system.
As you can see, thehybrid inverter uses batteries to store unused production during the day (red line down).
In the morning and evening, you benefit from the energy produced throughout the day (red line up).
The yellow highlight indicates the energy produced by the solar panels.
Electricity consumption from the grid is shown in blue (blue line down).
Electricity generated by the panels is fed back into the grid (blue line up).

We'll look at consumption over a full day

At 04:00 we use the public grid for our energy needs.

At 10:00 am: the panels produce 3002 W and the batteries recharge.

At 14:35: We produce (3170 W), the battery consumes 10.60 W and we inject 2665 W into the public grid.

At 9:00 p.m.: The battery is used to meet our energy needs.

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View the charge level of your batteries

Customizable battery recharge range

At 8 a.m. on 20/09, the battery is at 30% of its charge capacity, and the inverter will start recharging the battery. Recharging takes place at times that can be set from the inverter, so you can choose the time slots when youdecide to recharge the batteries; once at 100%, the inverter no longer sends energy to the battery, but sends unused energy to the public grid. From 7 p.m. the battery starts to discharge / we use the battery's energy to meet our energy needs. From 7pm the battery starts to discharge / we use the energy from the battery to meet our energy needs.

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Software

Sermatec application to download first. Configurable ONLY VIA ANDROID! (exists on Appel store BUT not usable)
Download the application directly by clicking here!
You can find the installation steps in the data sheets & documents. "Sermatec Parameter Manual-EN

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Connection to BMS module SC0500

ATTENTION: When connecting the Sermatec to the Pylontech BMS SC0500, cut the white/orange, orange and white/green cable.

Connect the cable to the BMS RS485 port.

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Example of current and voltage wiring

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Features

Product model

SMT-10K-TL-LV

PV input (DC)

Max.
PV power	14000 W

.

Max
PV voltage	1000Vdc

Nominal PV voltage

720Vdc

.

Max
PV input current	12.5 A / 12.5 A

MPPT voltage range

200 to 880 Vdc

2

MPPT number

Battery data

Battery voltage range

180 to 800 Vdc

Nominal battery voltage

400Vdc

Max.
charge/discharge current	25A / 25A

Mains AC data

Nominal AC power

10,000 W

Nominal mains voltage	230Vac / 400Vac;
220Vac / 380Vac; 3 / N / PE

Rated mains frequency

50 Hz / 60 Hz

Rated alternating current

14.5 A

Max.
Alternating current	16.7 A

0..

Power factor

.8cap .

0.8ind

THD

<

3

%

Load AC data (EPS / UPS / off-grid)

Rated power

10,000 W

Rated alternative voltage

400Vdc

；

380Vdc ； 3 / N / PE

Rated current

10 ms

Switching time

50 HZ / 60 HZ

Peak power at 25 ℃

14,5 A

Rated frequency

16.7 A

Max.
Alternating current	11 kW * 30 min 13 kW * 5 min; 15 kW * 5 s

THD （Linear load）

＜ 3%

Efficiency

MPPT efficiency

99.90%

European efficiency

97.00%

Max.
Efficiency	97.60%

Charge / discharge efficiency

97,6% / 96%

Protection function

Protection against reversed DC polarity

Yes

Anti-islanding

Yes

Residual current protection

Yes

circuits c

Protection against AC short
ircuits	Yes

Overcurrent / AC voltage protection

Yes

Integrated DC switch

Yes

Insulation monitoring

Yes

GENERAL data

（width

Size
X height X depth）	548 * 550 * 188 mm

Weight

＜ 40 kg

Standby power consumption

＜ 20 W

IP class

IP 65

-

Operating temperature

25 ℃ ...

+ 60 ℃

Altitude

＜ 2000M

Noise emission

＜ 30 dB

Cooling

Natural cooling

WIFI

Communication interface

、 GPRS （optical） 、 RS485。

Display

LED

Safety

EN 62109-1: 2010 / EN 62109-2: 2011 / IEC 62109-1 (ed.1) IEC 62109-2 (ed.1)

EMC

EN 61000-6-1: 2007 / EN 61000-6-2: 2005 / EN 61000-6-3: 2007 / A1: 2011 / EN 61000-6-4: 2007 / A1: 2011

standard

Grid connection

VDE-AR-N

4105: 2018 / NRS 097-2-1: 2017 / EN 50549-1: 2019 / AS / NZS 4777.2: 2015 / IEC 0-21: 2019 / PPDS2018 / IEC 61683: 1999 / RD 1699: 2011 / UNE 206006 / IN: 2011 / UNE 206007-1 / IN: 2013 / NTS 2019 (Type A, PO 12.2 2018-10) / C10 / 11: 2019-09