Briggs & Stratton 30K-3P-208V Sol-Ark Commercial Hybrid User Manual

INSTALLATION GUIDE

AND USER MANUAL

COMMERCIAL & INDUSTRIAL

NORTH AMERICA

EN

READ THE INSTRUCTIONS COMPLETELY BEFORE OPERATING THE EQUIPMENT

Check the utility voltage before turning ON the unit.

For proper operation, this unit REQUIRES closed-loop communications with a

compatible high voltage battery. Visit www.sol-ark.com/battery-partners for a

complete list of compatible high voltage batteries.

Verify voltage and the programmed “Grid Level” before connecting to the utility.

DISCLAIMER

UNLESS SPECIFICALLY AGREED TO IN WRITING:

Sol-Ark assumes no responsibility or liability for any damages, property loss, personal injury, or any adverse consequences resulting from

improper use and installation of the product or the failure to adhere to the guidelines provided in this document. Users are expressly advised

to follow the instructions and guidelines outlined in the documentation accompanying the product. Sol-Ark shall not be liable for any

damages or losses incurred due to deviations from recommended usage, installation, or maintenance procedures. By using the product,

users acknowledge their understanding of these disclaimers and agree to use the product at their own risk. Sol-Ark reserves the right to

update or modify product information, specifications, and guidelines without prior notice.

Sol-Ark retains the right to final interpretation of this document and all related materials pertaining to this product. This document is subject

to modifications, updates, revisions, or termination without prior notice. For the latest product information, please visit Sol-Ark’s official

website. www.sol-ark.com

This manual is only for the 30K-3P-208V Hybrid Inverter.

For support, contact:

(USA) +1 (972) 575-8875 ext. (2)

support@sol-ark.com

Table of Contents

IMPORTANT SAFETY INSTRUCTIONS ........................................................................................................................................................................................................... 5

1. Sol-Ark: At a First Glance .................................................................................................................................. 6

1.1 General Description ................................................................................................................................................................................................................................... 7

1.2 Specifications .............................................................................................................................................................................................................................................. 8

1.3 Connection Requirements ...................................................................................................................................................................................................................... 10

2. Installation ........................................................................................................................................................ 11

2.1 Mounting the Sol-Ark ............................................................................................................................................................................................................................... 11

2.2 Integrating Batteries ................................................................................................................................................................................................................................. 13

2.3 Battery Communications ......................................................................................................................................................................................................................... 14

2.4 Connecting PV Modules .......................................................................................................................................................................................................................... 15

2.5 Integrating a Generator ........................................................................................................................................................................................................................... 16

2.6 Grid Peak Shaving .................................................................................................................................................................................................................................... 16

2.7 Automatic Generator Start ...................................................................................................................................................................................................................... 16

2.8 Integrating Sensors and Accessories .................................................................................................................................................................................................... 17

2.9 Limit Sensors (CT sensors)....................................................................................................................................................................................................................... 19

2.10 Emergency Stop and Rapid Shutdown ............................................................................................................................................................................................... 21

2.11 Powering-up and Testing the Sol-Ark ................................................................................................................................................................................................. 22

2.12 Power Cycle Sequence .......................................................................................................................................................................................................................... 22

3. User Interface ................................................................................................................................................... 23

3.1 LED Indicators ........................................................................................................................................................................................................................................... 23

3.2 Main Menus ............................................................................................................................................................................................................................................... 23

3.3 Basic Setup ................................................................................................................................................................................................................................................ 25

3.4 Battery Setup ............................................................................................................................................................................................................................................. 26

3.5 Limiter ......................................................................................................................................................................................................................................................... 28

3.6 Grid Setup .................................................................................................................................................................................................................................................. 32

4. Installation Tips ............................................................................................................................................... 34

4.1 Battery Charge Controller ....................................................................................................................................................................................................................... 34

4.2 Grid Compliance Settings ....................................................................................................................................................................................................................... 35

5. Parallel Systems .............................................................................................................................................. 36

5.1 Before Enabling Parallel Operations ..................................................................................................................................................................................................... 36

5.2 Parallel Systems Programming Sequence ............................................................................................................................................................................................ 37

5.3 Troubleshooting Phase Sequence ......................................................................................................................................................................................................... 38

6. MySolArk: Remote Monitoring ..................................................................................................................... 39

6.1 MySolArk Setup Instructions ................................................................................................................................................................................................................... 39

6.2 LED Indicator and troubleshooting ....................................................................................................................................................................................................... 43

7. Wiring Diagrams ............................................................................................................................................. 44

8. Troubleshooting Guide .................................................................................................................................. 52

8.1 Sol-Ark Error codes .................................................................................................................................................................................................................................. 54

9. Warranty Verification Checklist .................................................................................................................... 55

10. GUI Screens ................................................................................................................................................ 57

IMPORTANT SAFETY INSTRUCTIONS

SYMBOLS THAT APPEAR IN THIS DOCUMENT

WARNING: This symbol indicates information that, if ignored, could cause serious injury, equipment damage, or death.

CAUTION: This symbol indicates information that, if ignored, could result in minor injury or equipment damage.

NOTE: This symbol indicates relevant information that is not related to hazardous situations.

WARNINGS

Read this entire document before installing or using the Sol-Ark 30K-3P-208V inverter. Failure to follow any of the instructions or

warnings in this document can result in electrical shock, serious injury, or death. Damage to the 30K-3P-208V inverter is also possible,

potentially rendering it inoperable.

High Life Risk due to fire or electrocution – ONLY qualified persons should install the Sol-Ark inverter.

The system must have Ground connections and Neutral connections. Ground MUST be bonded to Neutral ONLY ONCE in the circuit.

Solar PV+/PV- are UNGROUNDED. Note, you may ground PV Racking/Mounts, but doing so directly to the Sol-Ark will likely result in

damage in the case of a direct lightning strike to the PV array.

DO NOT connect the grid to the “LOAD” output terminal.

DO NOT reverse the polarity of batteries. Damage WILL occur.

DO NOT exceed 550Voc on any MPPT on the Sol-Ark.

DO NOT turn off the battery breaker if there is current flowing in or out of the battery in any amount.

DO NOT use impact drivers to tighten any fasteners on the Sol-Ark.

MUST use conduit (or double insulated wire) for AC wires entering/exiting Sol-Ark user area.

ALL terminals/breakers, including battery, MPPT, and AC Terminal Block inputs, should only have one conductor connected to them.

1. Sol-Ark: At a First Glance

INSPECT SHIPMENT

The box should include all items shown in the component guide. If there is damage or missing parts, immediately call the phone number

(USA) +1 (972) 575-8875 Ext. 2.

COMPONENT GUIDE

The Sol-Ark 30K-3P-208V system includes the following components:

Component

Description

Quantity

A

Sol-Ark 30K-3P-208V inverter

1

B

French cleat

1

C

M12x60mm expanding anchors

4

D

M4x12mm screws

9

E

CAT 5E communication cable

1

F

Wi-Fi / Ethernet antenna (dongle)

1

G

3mm L-type hex key for front panel screws

1

H

8mm T-type hex key for AC terminals

1

I

300A (Ø2”) Current transformers (CT sensors)

3

J

User manual

1

A B C D E

F G H I J

1.1 General Description

Component

Name

Component

Name

A

ON / OFF Button

H

Wi-Fi / Ethernet dongle

B

LCD touch screen

I

2x PV DC disconnects

C

Pin board 1 for sensors and accessories

J

4x MPPT inputs

D

Pin board 2 for sensors and accessories

K

LOAD terminal

E

Communication port board

L

NEUTRAL / GROUND Busbars

F

2x (50A) Battery port

M

GRID terminal

G

GEN terminal

A

B

C

D

F

G

H

I

J

L

M

K

E

1.2 Specifications

SOL-ARK 30K-3P-208V TORQUE VALUES APPLICATION NOTE

Do not use impact drivers to tighten any fasteners on the Sol-Ark

Terminal / Port

Torque [in-lb]

Torque [Nm]

“LOAD”

62 in-lb

7 Nm

“GRID”

62 in-lb

7 Nm

“GEN”

62 in-lb

7 Nm

Neutral / Ground (Busbar)

62 in-lb

7 Nm

Cover Screws

15.5 in-lb

1.75 Nm

Battery Connection

Push-in Cage Clamp

Temperature Derating Range

DC: 90°C – 100°C. Shutdown @ 100°C

AC: 75°C – 82°C. Shutdown @82°C

DAT A S H E ET

30K-208V

C&I Hybrid Inverter

Inverter Model Name:

30K-3P-208V

Sol-Ark Product SKU:

30K-3P-208V

Input Data (PV)

Max. Allowed PV Power (STC)

39,000W

MPPT Voltage Range

150-500V

Startup Voltage

180V

Max. Input Voltage

1

550V

Max. operating input current per MPPT

36A

Max. short circuit current per MPPT

55A

No. of MPP Trackers

4

No. of PV Strings per MPPT

2

Max. AC Coupled Input Power

30,000W

Output Data (AC)

Nominal AC Voltage (3Φ)

120/208V

Grid Frequency

50 / 60Hz

Real Power, max continuous (3Φ)

30,000W

Max. Output Current

83.4A

Peak Apparent Power (10s, off-grid, 3Φ)

45,000VA

Max. Grid Passthrough Current (10min)

200A

Continuous Grid Passthrough Current

180A

Power Factor Output Range

+/- 0.8 adjustable

Backup Transfer Time

5ms (adjustable)

CEC Efficiency

96.5%

Max Efficiency

97.5%

Design (DC to AC)

Transformerless DC

Stackable

Up to 10 in parallel

Battery Input Data (DC)

Battery Chemistry

Lithium iron phosphate

No. of Battery Inputs

2

Battery Input Terminal Rating

50A

Nominal DC Voltage

≥300V

Operating Voltage Range

160 - 500V

Battery Capacity Range

50 — 9900Ah

Max. Battery Charge / Discharge Current

100A (50A per input)

Charge Controller Type

3-Stage with Equalization

Grid to Battery Charging Efficiency

96.0%

Automatic Generator Start (AGS)

2 Wire Start - Integrated

BMS Communication

2

CANBus & RS485

General Data

Dimensions (H x W x D)

894 x 528 x 295 mm (35.2 x 20.8 x 11.6 in)

Weight

80 Kg / 176 lb.

Enclosure

IP65 / NEMA 3R

Ambient Temperature

-40 – 60°C, >45°C Derating

Noise

< 30 dB @ 25°C (77°F)

Idle Consumption - No Load

60W

Communication and Monitoring

Wi-Fi & LAN Hardware Included

Warranty

3

10 Years (15 Years)

Category

Certifications and Listings

(Grid Support Interactive Inverter)

UL 1741-2021 (UL1741SB), CSA C22.2 No 107.1-16,

IEEE 1547-2018 & 1547a-2020 & 1547.1-2020 (SRD V2.0),

UL 1741 CRD-PCS, UL1699B, CEC, SGIP

4

PV DC Disconnect Switch — NEC 240.15

Integrated

Ground Fault Detection — NEC 690.5

Integrated

PV Rapid Shutdown Control — NEC 690.12

Integrated

PV Arc Fault Detection — NEC 690.11

Integrated

PV Input Lightning Protection

Integrated

PV String Input Reverse Polarity Protection

Integrated

Surge Protection

DC Type II / AC Type III

1. See Installation Guide for more details on sizing array strings. The highest input voltage is based on the open-circuit voltage of the array at the minimum design temperature.

2. Active BMS communication is required for all lithium batteries. A list of compatible batteries can be found on our website.

3. 5-year extension is available for purchase by registered Gold level installers only.

4. Pending listing.

1.3 Connection Requirements

1. AC / DC Connection Requirements

All wire runs should be sized to be at or below a 2.5% voltage drop at full load. Wire size must comply with your local electrical code.

Port

Max Terminal Rating

Terminal Wire Size Range (min-max)

GRID

200A

AC

1/0 – 4/0 AWG

LOAD

200A

AC

1/0 – 4/0 AWG

GEN

200A

AC

1/0 – 4/0 AWG

MPPT

55A I

SC

12 – 10 AWG

Battery Port A

50A

DC

6 – 4 AWG

Battery Port B

50A

DC

6 – 4 AWG

2. Sensors and Communications Requirements

Component

Wire Size Range

Max Distance

CT Sensor

16-23 AWG

0’ – 10’ [3 m]: 16 AWG included

10’ – 20’ [6 m]: CAT6 extendable

Communications

24 – 23 AWG

0’ – 100’ [30 m]: 24 AWG

100’ – 400’ [120 m]: 23 AWG

RJ45 Parallel Communication

CAT 5E or better

0’ – 7’ [2.1 m]: Included

7’ – 20’ [6m]: Extendable

Batteries

AC Conductors

PV Conductors

Sensors

CT Sensors (Included)

0.8 in

[20.3 mm]

4/0 AWG MAX

1 in

[25.4 mm]

4 AWG MAX

10 AWG MAX

5/8 in

[16 mm]

23 AWG MAX

1/4 in

[6.35 mm]

1.85“

[47 mm]

10 ft

[3 m]

2. Installation

Backup Circuits

A. The “LOAD” connected service panel will be referred to as the Essential Loads Panel.

B. You must keep the essential loads panel within the limitations of the unit:

• Three phase power in a Wye configuration is calculated as follows → Real Power (W) = √3 * V

L

* I

L

* PF

Assuming a unity power factor (PF=1) then the following represents the maximum power levels for each condition.

• Grid Tie → 64.8 kW = 1.73 * 208V * 180A continuous (passthrough)

• Off-Grid → 30 kW = 1.73 * 208V * 83.4A continuous (batteries or PV) )

C. Verify that every load circuit power does not surpass the above limits.

Single System Install

A. FOR PARTIAL BACKUP: Use a Line Side Tap as point of interconnection to integrate the utility grid to the Sol-Ark inverter through

the “GRID” terminal.

• An external disconnect must be installed between the interconnection and the Sol-Ark. Size the disconnect according to code.

• Connect the "LOAD" output to the Essential Loads Panel. Follow electric code to select proper wire gauge.

B. FOR WHOLE-SITE BACKUP: Connect the utility grid directly to the “GRID” terminal.

• An external disconnect must be installed between the grid and the Sol-Ark. Size the disconnect according to code.

• Connect the “LOAD” output to the Main Service Panel. Follow electric code to select proper wire gauge.

It is possible to connect a generator, or an AC coupled source such as grid-tie string or micro inverters to the “GEN” terminal of the inverter.

Only one AC source can be connected to the “GEN” terminal at a time.

Partial Backup

Whole-Site Backup

2.1 Mounting the Sol-Ark

A. Considering the dimensions of the inverter, find a suitable location for the system. There must be at least 6 in [15 cm] of vertical

clearance and 2 in [5 cm] of side clearance for proper heat dissipation.

Max heat dissipation of 1,050W

AC

DC

PV

Battery

Grid

Main Panel

Subpanel

PV

Battery

Grid

Main Panel

≥ 6” [15 cm]

≥ 6”[15 cm]

≥ 2” min [5 cm]

6” if next to

another system

≥ 2” min [5 cm]

6” if next to

another system

≥ 20” [50 cm]

≥ 6” [15 cm]

≥ 6”[15 cm]

B. Under certain conditions, the National Electrical Code® specifies greater clearances. Ensure that the prescribed clearances in

accordance with the National Electrical Code®, paragraph 110.26 and Canadian Electrical Code® CSA C22.1 are adhered to.

C. The Sol-Ark 30K-3P-208V is a NEMA 3R - IP65 enclosure that is rated for outdoor installation but can also be installed indoors.

D. PROTECT THE LCD SCREEN from direct exposure to UV light.

E. Use screws or anchors suitable for the support surface and capable of supporting the weight of the inverter (176 lb / 80kg).

a. For Concrete or Masonry Mounting: Use a minimum of four (4) M12x60mm expanding anchors (included).

b. For Wood Frame Mounting: Use a minimum of four (4) 1/2in lag screws with flat washers (not included), making sure to

anchor into at least 2 framing members.

c. For Metal Framing Mounting: Use a minimum of four (4) 1/4in self-tapping metal screws with flat washers (not included).

d. In the case a different anchorage is required, calculate the number of anchor points needed to properly hold the weight

of the equipment.

F. Secure the inverter to the French Cleat with six (6) of the M4x12mm socket head screws provided.

Damage to the LCD Screen due to direct sunlight exposure will not be covered by warranty

G. Mount the inverter in the optimal orientation as shown below.

Suitable anchor for the

wall surface

2.2 Integrating Batteries

A. Sol-Ark 30K-3P-208V must be OFF while the batteries are being connected.

B. Ensure the external battery disconnect is OFF or arcing may occur. If your battery bank does not have built-in breakers, maintain

the necessary safety measures when handling the connections.

C. The 30K-3P-208V reaches a max battery charge/discharge of 50A per terminal for a total max of 100A if using both sets of battery

terminals. If only one set of terminals is used, the battery charge/discharge will be limited to 50A.

Sol-Ark 30K-3P-208V is a HIGH VOLTAGE BATTERY system. You MUST NOT exceed 500V

DC

as shown below. The HV battery must stay

within the 150V

DC

- 500V

DC

voltage range. DO NOT connect to any other nominal voltage that exceeds this limit.

a) single HV battery

b) bank of multiple HV batteries

The Sol-Ark inverter has two input battery terminals for single or dual battery connections. To wire a battery to the inverter, pull the actuation

levers and insert the 6-4 AWG battery conductor. DO NOT force open the battery actuation levers more than 45°.

DO NOT

reverse polarity. The system will be damaged, and warranty will be voided!

1. Multi-Terminal Installation

The two battery input terminals of the 30K-3P-208V will parallel batteries internally to ensure a common connection between battery banks

and simplify battery installations. If a charge / discharge rate of 100A is needed, the batteries must be connected to both input terminals. If

using 3 or more batteries, use external busbars for (+) and (-) connections.

a) single battery

b) single battery bank

c) dual battery bank

If a single battery is capable of charging / discharging above 50A, connect the battery to both input terminals. Otherwise, the charge and

discharge rate will be limited to 50A max. Connect batteries of the same brand, model, and chemistry to the terminals

2. Multi-System Installs

Please contact Sol-Ark technical support at support@sol-ark.com or (972) 575-8875 Ext. 2 before performing a multi-system installation.

A. ALL systems MUST be connected to their own HV battery / battery bank.

B. DO NOT parallel batteries between inverters.

2.3 Battery Communications

The Sol-Ark inverter can establish closed-loop battery communication through the RJ-45 port labeled “BMS1”. Configure and wire the HV

batteries so that there is one battery bank with a single communication source. Closed-loop communication is established by connecting

the communication cable to the “BMS1” port of the Sol-Ark inverter.

“🗹 Parallel Bat1&Bat2” setting on the Batt setup menu MUST be enabled and multi-terminal wiring MUST be carried out. See previous

section “Multi-Terminal Installation” for detailed wiring of multi-terminal, single battery bank installation.

Single battery bank communication

2.4 Connecting PV Modules

The Sol-Ark 30K-3P-208V has 4 independent MPPTs that support up to 2 PV strings each. MPPTs can handle a maximum

V

OC

of 550V

and

an

I

SC

of 55A

but will self-limit and operate at

I

mp

of

36A

max.

A. Max DC solar input = 39 kW (± 5%) | Max input power per MPPT = 9.75 kW | Max recommended input voltage per MPPT = 500 V

OC

| Max input current per MPPT = 36A (self-limiting).

B. Design for an input current of 36A per MPPT. The inverter will self-limit beyond 36A. If I

SC

exceeds 55A, damage will occur.

C. PV Source Circuit max voltage of 550V

OC

; damage can occur with PV strings whose open-circuit voltage exceeds 550V

OC

D. Strings in parallel on the same MPPT must have the same designed open-circuit voltage (Voc), otherwise the system will be

limited to the lowest string voltage.

i. PV1 A/B must have the same Voc.

ii. If the solar panels are oriented in different directions and connected in the same MPPT, there will be a loss in PV efficiency.

E. Per NEC Art 690.43, exposed non-current-carrying metal parts of PV module frames, electrical equipment, and conductor

enclosures of PV systems shall be connected to an equipment grounding conductor. All grounding conductors and grounding

electrodes should be installed according to NEC Art 690.47 or as required by the AHJ.

F. For ground mounted arrays, Sol-Ark recommends installing an auxiliary grounding electrode placed near the array to ensure

optimal earth-to-ground resistance of the grounding system. This auxiliary electrode would need to follow the requirements of

NEC Art 250.54.

G. Connect the solar panel strings using either of the following configurations:

“Y” connection

Individual strings

AC Coupling

The Sol-Ark 30K-3P-208V is a system that supports the addition of AC coupled solar panels. The max solar input power can be expanded by

coupling 3Φ micro or string inverters into the “GEN” terminals. A full AC coupled solar system is not recommended as power control and

monitoring is limited. Having DC coupled modules or a combination of DC coupled and AC coupled solar panels is always preferred.

3Φ AC coupled inverters need to be either UL 1741SA or UL 1741SB certified. This certification confirms the inverters’ ability to disconnect

from the grid based on frequency and ensures that the Sol-Ark will safely be able to frequency shift to control the AC coupled production.

Batteries are REQUIRED to AC couple solar panels to the “GEN” terminal. The AC coupled inverters can still produce solar power even

during grid outage events or in Off-Grid systems. Furthermore, the total AC coupling production will be monitored.

Maximum allowed AC coupling input: 30,000W

AC

In Off-Grid systems, Sol-Ark uses

Frequency Shift

technology to shut down AC coupled solutions when the battery is full. Grid-Tied AC coupled

solutions will

always

sell excess solar power back to the grid. “Limited to Load” will

NOT

limit production when AC coupled.

String PV1B

String PV1A

String PV1B

Y

Connector

Y

Connector

String PV1A

2.5 Integrating a Generator

Generators Smaller than 64.8kW → On “GEN” Input

1. ONLY supports three-phase 208V generators.

2. 200A rated “GEN” terminal. 180A continuous.

3. A THD (Total Harmonic Distortion) of less than 15% is preferred.

Generators Greater than 64.8kW → On “GRID” Input

1. ONLY supports three-phase 208V generators.

2. Optimal way to integrate generators for Off-Grid or Grid-Tied systems with automatic or manual transfer switches.

3. Programming “GEN Connect to Grid Input” is required: → Limiter → Other →

🗹 GEN Connect to Grid Input

.

4. DO NOT use “Grid Sell” in Off-Grid systems. Potential to damage the generator. Installation of CT sensors on generator lines is

only required if “Peak Shaving” is intended to be used.

Improve the Generator & Sol-Ark Compatibility

Navigate through the menus and program the following settings to improve the Sol-Ark and generator compatibility and operating range

to avoid frequent disconnections.

1. Change the grid mode to General Standard: → Grid Setup → Grid Selection → Grid Mode.

a. Tap and use the navigation arrows to cycle through the different grid modes. Choose “General Standard”.

2. Increase the frequency range of operation: → Grid Setup → Connect → Reconnect

a. Increase “Grid Hz High” to 65Hz.

b. Decrease “Grid Hz Low” to 55Hz.

c. Replicate changes for the “Normal Connect” settings.

3. Increase the voltage range of operation:

a. Increase “Grid Volt High” to 229V.

b. Decrease “Grid Volt Low” to 187V.

c. Replicate changes for the “Normal Connect” settings.

2.6 Grid Peak Shaving

1. To use Peak-Shaving on a generator, the equipment MUST be connected to the

“GRID” terminal of the inverter.

2. Peak-Shaving helps reduce grid consumption during peak demand by utilizing battery

backup power. It can also be used to prevent generator overload above a specified

power threshold.

3. Install the CT sensors on grid / generator lines L1, L2, L3. The arrows on the CTs MUST

point toward the inverter.

4. The Sol-Ark supplies power from the batteries whenever the “Power” threshold is met.

5. This mode will automatically adjust the “Grid Charge” amperage (A) to avoid generator

overloads during battery charging.

6. Grid Peak-Shaving will automatically enable “Time of Use” and MUST be configured.

2.7 Automatic Generator Start

1. “ 🗹 Gen Charge” is used when the generator is connected to the “GEN” terminal.

a. “Start V” or “Start %” is the set-point/condition that must be fulfilled to

automatically start the generator.

b. To charge from the “GEN” source, “🗹 Gen Charge” must be enabled.

c. Batteries will charge from a generator until the battery bank accepts 5% of

its programmed capacity in Amperes (A). This is equivalent to around 95% of

the state of charge (SOC).

Generator and grid charge settings

Grid peak-shaving settings

2. “🗹 Grid Charge” is used to charge the battery from the “GRID” source (grid or a generator).

a. “Start V” or “Start %” is the set-point/condition that must be fulfilled to start the battery charge from the “GRID” source.

This will auto-start a generator as well.

b. To charge the battery from the “GRID” source, “🗹 Grid Charge” must be selected: → Battery Setup → Charge.

c. From utility grid: the batteries will be charged to 100% SOC.

d. From generator: the batteries will charge until the battery bank accepts 5% of its rated capacity in Amperes (A). This is

equivalent to around 95% SOC.

If

“Time of Use”

(TOU) is enabled, a time to charge from that GRID or GEN source

MUST

be designated.

“🗹 Charge”

must be checked on

desired time intervals, otherwise the generator will not start automatically even if the Start V or Start % condition has been met.

Gen Charge / Grid Charge “A”

“A” is how many amps (DC) are supplied to the battery from the “GRID” or “GEN” source. Adjusting and limiting the Gen or Grid “A” value

will ensure that small generators are not overloaded when charging the battery bank.

If connecting more than one HV battery in parallel to the Sol-Ark inverter, divide the Gen or Grid “A” value by the # of batteries to estimate

the current (A) flowing to each HV battery.

2.8 Integrating Sensors and Accessories

Inverter pinouts for sensors and accessories

CN1

CN2

CN1

CN2

1. Sensor Pin Out (Located in Sol-Ark user area)

CN1:

• (1,2,7,8) CT-R: Current transformer (L1). Polarity sensitive.

• (3,4,9,10) CT-S: Current transformer (L2). Polarity sensitive.

• (5,6,11,12) CT-T: Current transformer. (L3). Polarity sensitive.

CN2:

• (1,2) G-Start: Normally open relay for generator two-wire start ( 12V, 100mA max)

• (3,4) Dry-1 and (5,6) Dry-2: Reserved

• (7,8) Optional RSD: 12Vdc (-3%) power supply for RSD transmitters (100mA max,

12Vdc, 1.2W)

• (9,10) Emergency stop: Normally open dry contact for emergency stop button.

• (11, 12) +/- : are not used at this time.

2. Communication Ports

• Meter: For external energy meter communication.

• Parallel_1 & Parallel_2: Parallel communications ports 1 and 2.

• CAN: Reserved.

• DRM: Reserved.

• RS-485: RS-485 port

• BMS1 & BMS2: BMS ports 1 and 2 for battery communications

3. CAN Bus & RS485 Ports

• CAN port data is in a proprietary format. Sol-Ark does not support 3

rd

party usage currently.

• The RS485/RTU port utilizes the MODBUS protocol, data is in a proprietary format. Please contact Sol-Ark to request an NDA if the

MODBUS mapping is required for your application.

4. GEN Start Signal (Two-wire start)

• Gen start relay: CN2, pins 1 & 2.

• The signal comes from a normally open relay that closes when the generator “Start” condition is met.

5. Wi-Fi / Ethernet Antenna (Dongle)

• Remote monitoring and software updates require an internet connection through the Wi-Fi /

Ethernet Antenna (Dongle).

• Compatible with Wi-Fi or Ethernet connections.

RS485

CAN

1

B-

2

A+

3

--

4

--

CAN Hi

5

--

CAN Lo

6

GND

7

A+

8

B-

8 7 6 5 4 3 2 1

2.9 Limit Sensors (CT sensors)

The CT sensors (or limit sensors) enhance system capabilities by enabling the use of the system work modes known as “Limited Power to

Home” (Meter Zero) and “Grid Peak-Shaving”. The CTs will measure and calculate total load demand which the Sol-Ark 30K-3P-208V will

then use to accurately supply and offset all existing loads (Meter Zero).

Off-Grid system do not require CT sensors unless “Grid Peak-Shaving” is used

1. CT Sensors Installation

• Install sensors on incoming electrical service wires (L1, L2, L3).

• Embossed arrows on the CT sensors must point towards the inverter.

• To ensure proper fit, check incoming wire diameters (grid or generator). If the sensors are too small, larger CTs can be purchased

by contacting sales: +1-972-575-8875 ext. 1 or [email protected]

• “Limited Power to Home” (Meter Zero) and “Grid Peak Shaving” require CT sensors.

• See section 3.5 “Limiter” for more information about the different work modes.

• See section 7 “Wiring diagrams” for more information on CT installation.

2. CT Sensor Size

• The Sol-Ark 30K-3P-208V includes three 300A CT sensors (Ø2”).

• Sol-Ark offers large 200A (Ø0.945”) and extra-large 600A (Ø1.976”) CT sensors upon request. Visit https://shop.sol-ark.com/ or

contact sales at +1 (972) 575-8875 / [email protected] to purchase bigger CT sensors.

• Default Sol-Ark CT ratio is 6000:1

Unless authorized,

DO NOT

change CT Ratio or warranty will be voided

3. Wiring the CT sensor

• Connect CT1 of line L1 to pins 1 (white) & 2 (black) of CN1 pin board.

• Connect CT2 of line L2 to pins 3 (white) & 4 (black) of CN1 pin board.

• Connect CT3 of line L3 to pins 5 (white) & 6 (black) of CN1 pin board.

• Keep the wires twisted (white-black) throughout the connection.

• If the wires need to be extended, use CAT 6 (shielded) cable to make an extension.

CTs

Meter

Main Panel

Line Side Tap

Subpanel

CT Sensors for multi-system installs

• Contact Sol-Ark technical support at [email protected] or (972) 575-8875 Ext. 2 before performing a multi-system installation.

• Each inverter will include three (3) CT sensors.

• Only one set of CT sensors need to be wired to the designated “Master” inverter.

• CT sensors are essential for multi-inverter systems as “Limited Power to Home” mode is highly recommended.

CT wire extensions with shielded CAT 6 cable

4. Automatic CT Limit Sensors Configuration

This function REQUIRES batteries to auto detect and auto correct CT orientation. AC coupled inverters need to be OFF during the detection

test. If this test is done with connected AC-coupled systems, a factory reset of the Sol-Ark must be performed. Install the CT sensor as

described previously. A battery connection and grid power are required before starting the automatic configuration.

→ Basic Setup → Advanced →

🗹

Auto detect Home Limit Sensors

Wait at least 10 to 15 seconds while the inverter performs the test. The inverter will alternate the current distribution in all lines, determining

the correct orientation of the sensor.

• On “Limited power to Home” mode (no Grid Sell), HM values will read close to zero (0). Keep in mind that all sensors have a 3% error.

• To avoid selling power to the utility use “Zero Export Power” equal to or greater than 20W.

• Buying power from the grid will display positive (+) HM values, while selling to the grid displays negative (-) HM values.

Grid

Phase A

Inverter

Phase A

Inverter

Phase B

Inverter

Phase C

Grid

Phase B

Grid

Phase C

2.10 Emergency Stop and Rapid Shutdown

The (B, B) emergency stop pins of the Sol-Ark 30K-3P-208V are an ordinarily open contact that triggers rapid shutdown (RSD) when closed.

RSD will cut all power including the Sol-Ark’s internal power supply and stop all AC outputs. The internal 12Vdc (-3%) power supply of the

Sol-Ark (CN2, pins 7 & 8) will disconnect any RSD transmitter that will then shut down all solar panels when the emergency stop button is

pressed.

• Emergency stop button connects to CN2, (B, B) pins 9 & 10 of the Sol-Ark.

• RSD transmitter connects to CN2, pins 7 & 8 (12Vdc power supply)

• Transmitters placed inside the user area of the Sol-Ark can cause interference.

• On multi-system installations, the emergency stop button must be wired to the designated “Master” inverter.

RSD Warning!

The Built-in 12Vdc power supply of the Sol-Ark 30K-3P-208V (Pins 7 & 8) is rated for

100mA (1.2W).

Do not exceed!

If unsure of the current (A) rating of the transmitter, contact the manufacturer before connecting

A transmitter that exceeds the maximum 100mA limit can still be integrated into the Sol-Ark inverter through an external power supply

connected to the “LOAD” output. Pressing the e-stop button will disconnect all AC outputs, cutting power to the “LOAD” connected service

panel which will initiate rapid shutdown.

Rapid Shutdown Recommendations

TIGO TS4-A-O

TIGO TS4-A-F

TIGO TS4-O

TIGO TS4-O-DUO

APsmart RSD S-PLC / RSD-D

Transmitter

Coil

Transmitter

Power Line

Communication

(PLC)

Emergency

Stop Button

To MPPT

Optimizers with RSD or standalone RSD

-

+

-

Receiver 1

Receiver 2

Receiver n

Transmitter Coil

Transmitter

Power Line

Communication

(PLC)

Emergency

Stop Button

To MPPT

Optimizers with RSD or standalone RSD

+

-

Receiver 1

Receiver n

V-

V+

External

PSU

N

L

“LOAD”

service panel

2.11 Powering-up and Testing the Sol-Ark

TURN ON the inverter with at least one power source: 1) Battery, 2) PV or 3) Grid

1. Check the voltage of the battery bank

A. Voltage of the battery must be between 150V

DC

- 500V

DC

.

B. Turn ON battery modules and ensure appropriate voltage on each battery. Verify nominal voltage of battery bank.

C. Turn ON the external battery disconnect. Verify that the voltage at the Sol-Ark terminals is adequate.

D. DO NOT reverse polarity. DO NOT turn OFF battery disconnect if any current is flowing in or out of the battery.

2. Check the voltage of each PV input circuit

A. Input voltage must not exceed 500V

DC

.

B. Input voltage must be above the startup voltage of 150V

DC

.

C. Do not ground PV+ or PV-.

D. Verify polarity in each PV string. Backward polarity will measure 0Vdc by the Sol-Ark and will cause long term damage.

E. PV alone turns LCD screen only. Inverter requires grid and/or batteries to operate, otherwise an “OFF” message will appear.

F. PV DC disconnect switches on the side of the inverter turn the PV ON or OFF.

3. Check GRID input voltage

A. Use the “GRID” terminals to measure AC voltage with a multimeter.

B. Measure line (L) to neutral (N) voltages on “GRID” terminals. Ensure 120V

AC

on all phases.

C. Measure line (L) to line (L) voltages on “GRID” terminals. Ensure 208V

AC

.

D. Verify that voltage between Neutral and Ground is 0V

AC

.

E. Verify that voltage between “GRID” L1 and “LOAD” L1 is 0V. Do the same for L2 and L3.

4. Power ON Sol-Ark 30K-3P-208V

A. Turn ON the external “GRID” disconnect. Wait for the “AC” LED indicator to turn on.

B. Turn ON the PV DC disconnect switches. Wait for the “DC” LED indicator to turn on.

C. PRESS down the power button to the ON position. Wait for the “Normal” LED indicator to turn on. This may take a few minutes.

D. Turn ON the external battery breaker if the system has batteries.

E. Turn ON the external “LOAD” and “GEN” breakers.

OFF

ON

2.12 Power Cycle Sequence

1. TURN OFF the external battery breaker if the system has batteries.

2. PRESS the power button, making sure it is in the OFF position. An “OFF” message will appear after the “Normal” LED turns off.

3. TURN OFF the built-in PV DC disconnect switches on the side of the inverter.

4. TURN OFF all AC breakers / disconnects (“GRID”, “GEN” and “LOAD”).

5. Wait a moment (~1 min) to ensure the inverter is completely de-energized.

6. Make sure that the Sol-Ark is properly connected to the batteries, solar panels, “GRID”, “GEN”, and “LOAD”.

7. Reverse the steps to turn ON the Sol-Ark.

3. User Interface

3.1 LED Indicators

DC

AC

Normal

Alarm

Green → DC Solar Panels connected

and providing voltage.

Green → Grid is connected

and providing voltage.

Green → Sol-Ark is fully energized*

and operating.

Red → Alarm state. Check the alarms menu.

Home Screen→ → “System Alarms”

OFF → Minimum MPPT voltage not

met, wrong polarity or no PV

DC

.

OFF → Grid voltage out of

range or Off-Grid system.

OFF → Not fully energized*, in fault

state or in passthrough mode.

OFF → No alarms / error codes / setting

change notifications

*Fully energizing

the unit constitutes at least: a) DC Solar panels

AND

Grid or b) Just batteries

3.2 Main Menus

1. Main Screen

2. Details Screen

• MPPT voltages MUST NOT exceed 550V.

• “TEMP” measures the internal temperatures of the AC conversion power electronics.

• “Grid” column measures: Voltage, Current, Power and frequency of the utility grid.

o If selling to the Grid: Watts = negative (-)

o If buying from the Grid: Watts = positive (+)

o HM: power measured by the external CT sensors. (L1, L2 & L3).

o LD: power measured by the internal sensor on “GRID” terminal. (L1, L2 & L3).

Opposing “Grid” or “HM” values indicate an incorrect installation of CT. See section 2.9 “Limit Sensor”

3. PV power Generation Graph

A. Tap the solar panel icon to display the PV power generation graph.

B. Displays power production over time for the PV array.

C. Use up/down arrows (↑, ↓) to navigate between days.

D. Month view/ year view/ total production.

PV power generation graph

Grid usage graph

Hold 4 s to force Smart Loads

Settings

Details Screen

Solar power production

Grid power

Sell (-) / Buy (+)

Load power

consumption

Battery power

Charge (-) / Discharge (+)

Total P & P

3

Φ

V, I & P of MPPT1

Internal AC temperatures

Battery 2:

V / %, I and T

GEN source V Φ, P Φ & f

Output VΦ, IΦ, PΦ & f

V, I & P of MPPT2

V, I & P of MPPT3

V, I & P of MPPT4

GRID VΦ & f

PΦ measured by external sensors

PΦ measured by internal sensors

Battery 1:

V / %, I and T

LOAD VΦ, & PΦ

4. Grid Usage Graph

A. Tap the grid icon to display the grid usage graph.

B. Displays power drawn from grid (+) / sold to the grid (-).

C. Values above the line indicate “power bought” from the grid.

D. Values bellow the line indicate “power sold back” to the grid.

E. This view can help to determine when the peak power is used from the grid.

5. System Setup Menu

3.3 Basic Setup

Display

Brightness: Brightness adjustment (+, -).

Auto Dim: Must be enabled at all times to validate the warranty of the LCD screen.

Beep: Enable / disable the alarm sound.

Time

Time Sync: Automatically syncs with the internet for daylight saving time changes (Enabling “Time sync” is recommended).

Seasons: Setup and customize the seasons for TOU.

(1)

(2)

(3,4)

(5)

Information

provided by the

BMS

Advanced

Solar Arc Fault ON: Enables Arc fault detection algorithm on the MPPTs.

Clear Arc Fault: Command to clear an Arc Fault. It must be executed manually every time the system detects an F63 Arc_Fault

alarm. See section 8.1 "Sol-Ark Error Codes" for more detail.

Gen Limit Power: Limits the power drawn from the “GEN” AC source. The inverter will reduce battery charge when value is reached.

Load Limit Power: Sets a limit to the total “LOAD” output power. The max output power of the inverter is programmed by default.

Grid-Peak Shaving: Sets a “GRID” consumption threshold that allows use of battery backup power during peak demand. External

CT sensors are required. Peak shaving can be used on a generator provided it is wired to the “GRID” terminal.

Auto detect home Limit Sensor: Detects and auto-corrects the polarity of the CTs. See section 2.9 for details.

CT Ratio: Specifies the transformation ratio of the CT. Default value of 6000:1 DO NOT change or warranty will be voided.

UPS Time: Backup transfer time to essential loads upon grid disconnection. Default value of 5ms.

Factory reset

Restrictions: Changes to these settings must be previously authorized by Sol-Ark technical support agents.

Parallel

Contact Sol-Ark technical support at support@sol-ark.com or (972) 575-8875 Ext. 2 before performing a multi-system installation.

Parallel: Enables communications between parallel inverters. “Master” and “Slave” inverters must be programmed.

MODBUS SN: Identification number for each system configured in parallel (1,2,3,4, n).

See section 5 “Parallel Systems” for more information

3.4 Battery Setup

Batt

Batt Capacity: Specifies the capacity of the battery bank. Value expressed in Amp Hour (Ah).

Batteries in series → Voltage adds up (V).

Batteries in parallel → Capacity adds up (Ah).

Max A Charge: Sets the maximum charge current (A) rate to the batteries when charged from solar power → 50 max allowed. 100A

max total if using both battery terminals.

Max A Discharge: Sets the maximum discharge current (A) rate from the batteries → 50 max allowed. 100A max total if using both

battery terminals.

For Off-Grid systems, the battery bank will discharge 150% of this value for a 10 second surge before the inverter faults to

prevent battery damage.

BMS Lithium Batt: Enables closed communications with lithium batteries. Serial Number (01,02, ...) must be specified according to

communication protocol.

Use Batt V Charged: Displays battery charge in terms of voltage.

Parallel bat1&bat2: Must be checked when using both battery inputs for the same battery bank. When enabled, the inverter will

expect a single battery communication source. Follow Battery Communication instructions from section 2.3.

Charge

Float V: Lower steady voltage at which the battery is maintained after being fully charged. Set according to manufacturer specs.

Gen Charge: Uses the “GEN” AC source to charge the battery bank.

a. Start V: Voltage at which the system will auto-start and allow a generator or AC source to charge the battery.

b. Start %: SOC at which the system will auto-start and allow a generator or AC source to charge the battery.

c. A: Maximum rate of charge to the batteries (per terminal) from the generator or AC source (DC amps). Set value according

to the generator size.

Grid Charge: There are two scenarios in which this option is used:

a. Grid connected to “Grid” input: The inverter will limit the charge rate to the set value in “A” and the battery will charge to

100% SOC.

b. Generator connected to “Grid” input: It will be necessary to select “🗹 GEN connect to Grid input”. The system will use

“Start V”, “Start%” and “A” conditions to charge the battery and stop charging at 95% SOC. Adjustable upper limit if

Time of Use is enabled.

Gen Force: Test function for generator auto-start. Enable and press OK to close normally open relay (CN2, pins 1,2) and force the

generator on. Disable and press OK to disengage. The generator will not provide power during this test if grid power is available.

The gen must be in automatic mode if applicable and must have a two-wire start (dry-contact, normally open) connected to the Sol-Ark.

Discharge

Shutdown: Battery voltage or % at which the inverter will shut down to protect the battery from an over discharge situation (battery

symbol on the home screen will turn red).

Low Batt: Low battery voltage or % (battery symbol on the home screen will turn yellow). Stopping point for TOU.

Restart: Battery voltage or % at which AC output will resume after previously reaching “shutdown”.

Batt Empty V: Sets the empty voltage and associates this voltage to 0% SOC. This value determines the lowest % SOC limit.

BMS_Err_Stop: Enables system stop when there is loss of battery communications.

Continuous GEN input/output of 180A.

DO NOT

EXCEED

.

Smart Load

A. This mode uses the “GEN” input as a load output that delivers power when the battery exceeds a user programmable threshold or

when the Sol-Ark is connected to the grid.

B. When “🗹 Use gen input as load output” is enabled, the “GEN” input turns into an output to power high-power loads such as a water

heater, irrigation pump, AC unit, pool pump, or any other load.

C. When “🗹 On Grid always on” is enabled, the “GEN” terminal will always output power as long as the grid is connected, regardless

of battery charge.

Smart Load OFF Batt: Battery voltage or % at which the “GEN” terminal will stop outputting power.

Smart Load ON Batt: Battery voltage or % at which the “GEN” terminal will start outputting power.

Solar Power (W): Amount of PV production needed before “GEN” terminal starts outputting power.

AC Coupling Settings - (For AC Coupled Input)

A. Grid-tied systems with AC coupled solar arrays must have “🗹 Grid Sell” enabled. Ensure you are allowed to sell back to the grid.

B. To use the “GEN” terminal as an AC coupling input for micro inverters or string inverters, enable " 🗹 For AC Coupled Input to Gen”.

C. In off-grid systems, the Sol-Ark will use frequency shifting to control the AC coupled solution based on the battery SOC. The

meaning of “Smart Load OFF Batt” and “Smart Load ON Batt” will change in this mode.

Smart Load OFF Batt: The % SOC at which the AC coupled inverters turn OFF. 90% recommended.

Smart Load ON Batt: The % SOC at which the AC coupled inverters turn ON. 80% recommended.

3.5 Limiter

Limiter

The Sol-Ark 30K-3P-208V inverter will simultaneously utilize different available power sources to satisfy load demand in the electrical

service panels (essential loads panel / main service panel). The following work modes allow the user to determine how power is

generated and utilized.

Grid Sell

Grid Sell: The inverter will produce as much power as it has available from PV array according to the programming. The maximum

power that can be generated from DC coupled arrays and sold to the grid is 30,000W.

General description:

a. This mode allows the inverter to sell back power generated from the solar arrays up to a programmable limit.

b. The inverter will only measure loads connected to the “LOAD” terminal.

c. The inverter will measure all power in / out of the “GRID” terminal as grid either consumption (+) or grid sell back (-).

Grid Sell

Limited Power to Home

This work mode

REQUIRES

batteries

Limited Power to Home (Meter Zero): This mode limits the energy produced by the inverter to satisfy the total demand (essential

loads panel + main service panel). In this mode, the inverter delivers power to the “LOAD” terminal (essential loads panel) + the

“GRID” terminal (main service panel). CT sensors MUST be installed. These sensors measure load consumption in the main service

panel to offset total load demand and prevent selling to the utility. This system work mode is useful for users that don’t have a permit

to sell back. See section 2.9 “Limit Sensors” for proper external CT installation.

General description:

a. Power is delivered to all home loads without selling excess solar to the grid. This mode is suitable for systems where selling

to the utility grid is not allowed.

b. External CT sensors are required for proper operation.

c. Monitored loads will be the addition of the main service panel + essential loads panel.

d. Energy Priority: 1. Solar PV Power | 2. Grid Power | 3. Batteries | 4. Generator

Limited Power to Home

Limited Power to Home + Grid Sell: This mode will NOT limit solar production to home demand. In this mode, the inverter delivers

power to the “LOAD” terminal (essential loads panel) + excess power to the “GRID” terminal (main service panel AND grid). The

Sol-Ark will monitor grid sell and load consumption simultaneously (with +/ - 3% error from CT sensors). The CT sensors MUST be

installed. The inverter will sell excess solar power up to a programmable limit. See section 2.9 “Limit Sensors” for proper external

CT placement.

Limited Power to Home + Grid Sell

Limited Power to Load

This work mode

REQUIRES

batteries

Limited Power to Load: This mode limits the solar production to cover “LOAD” demand (essential loads panel) exclusively. In this

mode, the system disregards loads in the main service panel and will not deliver power to the “GRID” terminal.

General description:

a. Power is limited to the “LOAD” demand. It will NOT produce more power than necessary.

b. Power will NOT be delivered to the “GRID” terminal (NO grid sell).

c. Monitored loads will be exclusive to the essential loads panel.

d. This mode is recommended for off-grid applications.

e. Energy Priority: 1. Solar PV Power | 2. Grid Power | 3. Batteries | 4. Generator

Limited Power to Load

Limited to Load + Grid Sell: This mode will NOT limit solar production to “LOAD” demand. The inverter delivers power to the

“LOAD” terminal (essential loads panel) + excess power to the “GRID” terminal (main service panel AND grid), however it will ONLY

track “LOAD” demand and sell excess solar up to a programmable limit. “GRID” loads cannot be measured, only the total output

through the “GRID” terminal. This mode is recommended for single inverter systems or for whole-site backup installations.

Limited Power to Load + Grid Sell

Time of Use

Time Of Use (TOU): This mode combined with “Limited Power to Home” or “Limited Power to Load” allows the use of battery backup

power to reduce consumption from the grid during specific time intervals. Battery power will cover load demand at a programmable

power rate “Power(W)” down to a programmable “Batt (V / %SOC)”. You can configure six different time intervals over a 24-hour

period to cover a wide range of battery discharge or charge behaviors.

General description:

a. Uses battery power to reduce the power consumption during user defined time intervals.

b. Power (W) dictates the rate at which the battery discharges to assist with load demand.

c. Batt (V or %) dictates the lower discharge limit or upper charge limit.

d. Energy Priority: 1. Solar PV Power | 2. Batteries (down to programmed discharge V or %) | 3. Grid Power | 4. Generator.

Limited Power to Home + TOU

Time: Programable time intervals over a 24h period. All time slots MUST follow chronological order and must be programmed.

Power(W): Sets the maximum discharge rate of the battery during the corresponding time slot.

Batt: V or % used to specify a lower discharge limit or upper charge limit whenever “🗹 Charge” is enabled. Grid-tied systems

will not allow TOU to discharge lower than “Low Batt V/%”. Off-grid systems allow TOU discharge down to “Shutdown V/%”.

🗹 Charge: During the hours selected, it is allowed to charge batteries from an external AC source up to a programmed voltage or

%. If the external AC power source is a generator, the “Start V” or “Start %” condition must be fulfilled first. If available, the solar array

will always charge the batteries at 100% regardless of “🗹 Charge” in TOU.

🗹 Sell: Allows batteries to discharge and sell power to the grid at the programable “Power(W)” rate. “🗹 Grid Sell” MUST be enabled.

Do

NOT

enable “Charge” and “Sell” at the same time

Other

GEN Connect to Grid Input: Specifies when a generator is connected to the “GRID” terminal.

Zero Export Power: Minimum power imported from the grid. Helps avoid selling back by ensuring constant grid consumption. The

value can be set between 1 – 100W (recommended 20W).

Batt First: Default and recommended option. Sets the solar power priority of the system to charge batteries first. Do NOT change

unless instructed by Sol-Ark technical support.

Load First: Sets the solar power priority of the system to cover loads demand first and deliver remaining power to batteries. Only

recommended for very specific situations.

3.6 Grid Setup

Grid Selection

Grid Mode: Tap and use navigation arrows to cycle through different grid modes:

1. General Standard: Applies general grid interconnection standards. Enables grid frequency and voltage adjustments.

(Useful for off-grid applications with backup generators).

2. UL1741 & IEEE1547: Applies UL 1741 and IEEE 1547 grid interconnection requirements and standards.

3. CPUC RULE21: Applies California’s grid interconnection requirements and standards.

4. SRD-UL-1741: Applies UL 1741SB grid interconnection requirements and standards.

Grid Frequency: Frequency of the AC sine wave.

Grid Reconnect Time: The amount of time in seconds the inverter will wait before reconnecting to the grid.

Fixed PF: Allows for power factor correction, ±0.8 to 1.0

Fixed Q: Allows for power factor correction based on desired reactive power percentage.

Grid Level: Tap and use navigation arrows to cycle through different nominal grid voltage levels. Grid level must be selected

according to nominal grid voltage.

1. LN:120VAC LL:208VAC

2. LN:115VAC LL:200VAC

3. LN:133VAC LL:220VAC

Phase Type: Tap and use navigation arrows to specify phase sequence.

1. 0/240/120: Positive sequence A-B-C

2. 0/120/240: Negative sequence A-C-B

Connect

Reconnect: Parameters used to determine an allowable range of frequency and voltages to dictate a reconnection to the grid after

initial grid loss. Frequency and voltages must be within these margins during Grid Reconnect Time to allow grid reconnection.

Parameters will be set automatically based on selected grid mode compliance, unless “General Standard” is selected.

Normal connect: Parameters used to determine an allowable range of frequency and voltages to retain connection to the grid

following a reconnect and normal operation.

Parameters will be set automatically based on selected grid mode compliance, unless “General Standard” is selected.

Reconnect Ramp Rate: Reconnection power ramp time in seconds.

Normal Ramp Rate: Startup power ramp time in seconds.

IP

HV1/HV2/HV3: Overvoltage protection point.

LV1/LV2/LV3: Undervoltage protection point.

HF1/HF2/HF3: Over frequency protection point.

LF1/LF2/LF3: Under frequency protection point.

F(W)

F(W): Enables the use of Frequency-Watt. The Sol-Ark regulates its power output to the grid as a function of the frequency to support

grid stabilization during over and under-frequency conditions.

Droop F: Percentage of inverter’s nominal power increase / decrease per Hert (Hz).

Start freq F: Frequency at which the inverter will start decreasing active power by the programmed Droop F percentage.

Stop freq F: Frequency at which the inverter will stop decreasing active power by the programmed Droop F percentage.

V(W) / V(Q)

V(W): Enables the use of Volt-Watt. The Sol-Ark regulates active power output to the grid as a function of voltage to support

stabilization during over and under-voltage conditions.

V(Q): Enables the use of Volt-VAr. The Sol-Ark regulates reactive power output to the grid as a function of the voltage to support

stabilization during over and under-voltage conditions.

V, P & Q: Percentage of nominal grid voltage (V) to which the Sol-Ark will reduce its active power (P) or reactive power (Q).

P(Q) / P(F)

P(Q): Enables the use of Watt-VAr to regulate reactive power output according to programable active power parameters.

P(F): Enables PF regulation according to programmable active power parameters.

Follow electrical grid code before changing grid settings

4. Installation Tips

Off-Grid Installation Tips

1. Limit sensors (CTs) are not required for completely off-grid installations unless using “Grid Peak Shaving” for a generator connected

to the “GRID” terminal.

2. Connecting generators to the “GRID” terminal is recommended to facilitate the integration “GEN” connected service panel. This

setup enables the utilization of the “Smart Load” function.

3. There is no need for a transfer switch. Connect the “LOAD” output to the main panel.

4. DO NOT use “Grid Sell” mode when Off-Grid. ONLY “Limited Power to Load” (default).

5. When using a Generator in an Off-Grid situation, it is recommended to change the “Grid Mode” to “General Standard” and a “Grid

Reconnect Time” to 30 seconds. See section 2.5 “Integrating a Generator” for detailed instructions.

6. The Auto Gen-Start activates when the battery voltage (V) or percentage (%) reaches the pre-set “Start V / %” value. Subsequently,

the generator will sustain the charging process until the batteries reach approximately 95% capacity. This is a non-modifiable

upper limit unless Time of Use is enabled and programmed.

7. If planning on integrating a wind turbine, a ≥300V charge controller with a dump load MUST be incorporated to prevent battery

overcharge. This charge controller must be connected directly to the battery bank.

8. Remember to set the battery capacity and reasonable charge/discharge rates.

Grid-Tie and No Battery Install Tips (Passthrough mode)

1. Check the “🗹 No Battery” setting: → Battery Setup → Batt → No Battery . The inverter will fault momentarily.

2. A complete Power Cycle IS REQUIRED when changing the battery mode to “No Battery” (see section 2.12 “Power cycle

Sequence” for detailed instructions).

3. Enable “🗹 Grid Sell”: → Limiter → Grid Sell. Make sure to disable all other modes.

4. Tap the battery Icon to access the “Details Screen” and verify grid parameters and power import / export.

4.1 Battery Charge Controller

4-Stage Charging

The MPPT has a 4-stage battery charging

algorithm for rapid, efficient, and safe battery

charging. The next figure shows the stage

sequence.

Bulk Charge Stage

In the Bulk Charge stage, the battery is not at a

100% state of charge and has not yet reached the

Absorption voltage setpoint. The controller will

deliver 100% of available solar power to recharge

the battery.

Absorption Stage

When the battery has reached the absorption voltage setpoint, the Sol-Ark inverter uses constant-voltage regulation to maintain battery

voltage at the absorption setpoint, preventing overheating and excessive battery gassing. The battery is allowed to come to a full state of

charge at the absorption voltage setpoint. Absorption lasts until the battery charge amperage (A) rate reaches 2% of the programmed

capacity (Ah).

Float Stage

After the Absorption stage charges the battery fully, the MPPT reduces the battery voltage to the float voltage setpoint. The Float stage

provides a meager rate of maintenance charging while reducing the heating of a fully charged battery. The purpose of the Float stage is to

protect the battery from long-term overcharge.

Charge controller curve

BULK

ABSORPTION

FLOAT

V

t

Equalization V

Absorption V

Float V

Shutdown V

Empty V

Low Batt V

Restart V

Night

4.2 Grid Compliance Settings

HECO Grid Compliance Verification for Sol-Ark

In cases where HECO compliance requirements are mandated, it is essential to program the following grid parameters in accordance with

the HECO specifications. Follow the next GUI screens, program the settings, and verify alignment with HECO compliance.

5. Parallel Systems

Contact Sol-Ark technical support at support@sol-ark.com or (972) 575-8875 Ext. 2 before performing a multi-system installation.

5.1 Before Enabling Parallel Operations

A. Make sure all units in parallel have the same software version by verifying

the “COMM” and “MCU” numbers on System Setup.

B. Go to https://www.sol-ark.com/software-update/ to schedule an update

or call/email Tech Support for assistance: [email protected]

C. Parallel systems REQUIRE that each inverter has its own HV battery /

battery bank. If you do not have batteries, keep all Sol-Ark inverters OUT

of parallel and set every System to “Grid Sell” Mode.

D. All INPUTS/OUTPUTS must be shared among ALL parallel inverters, with

the exception for HV Batteries and DC solar panels.

DIP Switch Configuration for Parallel Systems

In parallel systems, set the “DIP Switches” shown in the following, according to the table below.

Parallel systems with 2 inverters must have their DIP switches on the ON position

Inv 1 (Master)

Inv 2

Inv 3

Inv 4

Inv 5

Inv 6

Inv 7

Inv 8

Inv 9

Inv 10

OFF

ON

OFF

ON

OFF

ON

OFF

ON

OFF

ON

OFF

ON

OFF

ON

OFF

ON

OFF

ON

OFF

Software version check

Parallel Systems Sol-Ark 30K-3P-208V @ 120/208V 3-Phase

# of inverters in parallel

Continuous output power (kW)

Cont. Grid

Pass Through Current (A)

Peak power 10 sec

(kVA)

1

30

180

45

2

60

360

90

3

90

540

135

4

120

720

180

5

150

900

225

6

180

1080

270

7

210

1260

315

8

240

1440

360

9

270

1620

405

10

300

1800

450

5.2 Parallel Systems Programming Sequence

1. Program each inverter for parallel operation: → Basic Setup → Parallel →

“🗹 Parallel”

2. Assign a “Master” inverter, Modbus SN: 1

3. Assign all other units as “Slave” | Modbus SN: 2,3,4…etc.

4. Connect communication cables between the inverters using the RJ45 cable (yellow ethernet cable) in daisy-chain configuration

between ports: “Parallel_1” or “Parallel_2” from Master to Slave / Slave to Slave.

5. Perform a power cycle (see section 2.12 “Power Cycle Sequence” for power cycle sequence instructions).

6. Once the power cycle is completed, turn on the “Slave” units FIRST. Then turn ON the “Master” LAST.

7. Inverters will likely fault momentarily with F29 and F41 codes until all inverters are ON.

When integrating a generator, it must be connected to all the systems in parallel. The inverter assigned as “Master” will control the two-wire start feature

Parallel setup tab

If an inverter goes into a fault state, all other units will stop and follow. The system will automatically self-reboot. If the system faults 5 consecutive

times, it will stop completely and it will require a manual restart. See section 2.12 “Power cycle sequence” for detailed instructions.

5.3 Troubleshooting Phase Sequence

If the screen of the Sol-Ark inverter shows the error shown below, ensure the phase sequence follows the “Phase Type” programmed

under → Grid Setup → Grid Selection. The message “Grid Phase Wrong” is displayed when the inverter does not detect the correct phase

sequence. This situation can cause overloads faults in the system (F18, F26, F34) even with the “LOAD” disconnected and WILL CAUSE

DAMAGE to the equipment if it is not corrected.

If the programmed phase type is “0/240/120”, ensure the wiring follows a positive sequence A-B-C. If the programmed phase type is

“0/120/240” ensure the wiring follows a negative sequence A-C-B.

How to find an incorrect phase if prompted “Grid Phase Wrong”?

• Measure L-L voltages from “GRID” to “LOAD” terminals.

• Voltage between lines must be 0Vac.

• Measuring voltage different than 0Vac means the lines are not the same phase.

Be sure to check both “GRID” and “LOAD” terminal connections; both must be correct. If the error persists you will need to check your AC

connection beyond the inverter and you will need to verify that the phases are correctly labeled from your meter.

0/240/120

0/120/240

A

B

C

A

B

C

A

C

B

A

C

B

6. MySolArk: Remote Monitoring

"MySolArk" is a powerful and comprehensive tool designed for remote system monitoring of Sol-

Ark inverters and solar systems. This remote monitoring solution offers detailed insights into

energy generation and power consumption, allowing users to track system performance with great

precision. MySolArk displays all relevant electrical data on easy-to-understand energy generation

graphs, providing a comprehensive overview of electrical usage.

Beyond its monitoring capabilities, MySolArk offers users the flexibility to remotely adjust inverter

settings, allowing them to seamlessly configure their system from any location. This ensures that

users can fine-tune parameters to optimize performance effortlessly. With MySolArk, users can

confidently manage their solar systems and inverters to ensure peak performance and efficiency

at all times. Visit www.mysolark.com to access the desktop version of MySolArk.

6.1 MySolArk Setup Instructions

Connection to MySolArk through Ethernet

A. Remove the plastic enclosure of the dongle by pressing the plastic latches with a flat screwdriver as shown in the figure below.

B. Insert the ethernet cable through the plastic enclosure and connect the cable to the RJ45 port.

C. Reassemble the dongle housing and plug the dongle into the Sol-Ark, securing it with screws. You will see solid red and green

lights after a couple of minutes.

D. Follow “STEP 1” instructions on the following page in order to create a plant on MySolArk.

Connection to MySolArk through Wi-Fi

A. Plug the Wi-Fi dongle into the Sol-Ark DB-9 port.

B. Use two M4X10 screws to secure the dongle to the port.

C. Follow “STEP 1” through “SETP 3” in order to:

a. Create a plant on the MySolArk monitoring platform.

b. Connect the dongle to MySolArk through a Wi-Fi network.

STEP 1: Create a “Plant” on MySolArk

A. Download and install the “MySolArk” app for android or apple smartphones. QR codes are provided below.

Google Play Store

MySolArk

Apple App Store

B. Create a MySolArk account and login.

C. Create Plant.

For Installers

Installers are advised to first create the plant and configure the system before sharing it with the owner. Once the plant has been created and configured, the

installer can share and grant manager permissions to the owner by navigating to “My Plants” → “…” → “Share” → “Add Account”. The homeowner must

create their own MySolArk account first.

1

2

3

4

5

Login

Sign Up

E-mail & verification Code

6

EA##########

############

8

7

9

Create plant

Configure network

Plant information

Scan QR code or type manually

STEP 2: Configure Wi-Fi network though MySolArk

D. Configure Wi-Fi network.

NOTE: The Wi-Fi configuration tool can be accessed at any other time by tapping “Me” at the bottom right corner, then “Tools” and finally

“Wi-Fi configuration”. STEP 3 shows an alternative method of connecting the Wi-Fi dongle to a local network through an IP address.

Password

Connection

Turn inverter ON

to power dongle

Accept conditions

11

12

10

13

E4A0########

EAP-#####

E4A0########

EAP-#####

Confirm Wi-Fi network

Connect

E4A0########

EAP-#####

My local network

My local Wi-Fi network

17

15

16

14

1

2

STEP 3 (alternate method): Configure Wi-Fi Network Through an IP Address

A. An alternative to the “Distribution Network” configuration at the end of step C or the use of the “Wi-Fi configuration” tool, is by

configuring a Wi-Fi network through an IP address.

B. On a Smart Phone or Computer connect to the EAP-##### network. You can do this by going to: Settings → Wi-Fi → Select the

EAP-##### network → Password= 12345678. The EAP-##### network contains the last 5 digits of the Dongle Serial Number. You

can find this number on the label.

C. A message such as “Connected without internet” will appear once the device is connected to the EAP-#####.

EAP-##### Network Password= 12345678

NOTE:

The Wi-Fi dongle does NOT provide internet access. It needs an external internet provider to connect to.

The dongle is compatible with Wi-Fi signal broadcasted at 2.4 GHz

(it is not possible to use 5 GHz)

D. Once connected, open an internet browser on that same device such as Safari, Chrome, Firefox, Edge, or any other browser.

E. On the address bar (http://.........), type the following IP address: 10.10.10.1 as shown in the figure below. If you cannot access the

configuration page, try again on a different device.

F. Scroll down to the "Wlan Connection" section and press the “Scan” button to scan for local Wi-Fi networks.

G. Nearby Wi-Fi networks will appear. Select the local network you would like to connect to, input your credentials, and tap “Connect”.

H. Once connected, a “Connection Successful” message will appear. Press the “Save” button next to “Scan” to save settings.

I. Wait a moment (~5 minutes). The dongle will then connect to the Wi-Fi network and will now have access to MySolArk.

NOTE: DO NOT connect to the EAP-##### network as that is the Wi-Fi dongle itself. The device does not provide internet access.

a) Internet browser IP address

b) Wi-Fi network scan

E4A0 #### ####

Example 1

Example 2

Example 3

My local Wi-Fi network

Example 5

Example 6

Example 7

Example 8

Example 4

If the connection is a success, you will see the following LED indicators.

o SOLID : Connected and powered by the Sol-Ark inverter.

o SOLID : Connected to the router and to MySolArk.

Wi-Fi dongle LED indicators

Connecting the through the 10.10.10.1 IP address is only meant to provide internet access to the Wi-Fi dongle.

Users must still create a MySolArk account and must create a Plant.

Visit www.mysolark.com to access the desktop version of MySolArk.

6.2 LED Indicator and troubleshooting

When both the red and green LEDs on the Wi-Fi dongle are consistently illuminated, it signifies normal operation, while flashing indicates

data transmission. If this isn't the case, reference the next table of LED indications for troubleshooting and corrective measures.

RED LED: Device communication indicator.

GREEN LED: MySolArk server communication indicator.

LED

State

Indication

Initial flashing, then constant illumination

Normal communication.

Initial flashing but no further illumination

Communication failure. Check proper device connection.

LED not illuminating

Power supply or device is abnormal. Contact technical support.

5 second illumination interval

Normal communication.

1 flash every minute

Router not connected.

3 flashes every minute

Connected to router but no internet access. Usually, a VPN or firewall

issue. Ports 80 and 51100 must be enabled.

4 flashes every minute

Device communication error. Contact support.

2 synchronized flashes

Ethernet cable inserted

3 synchronized flashes

Ethernet cable disconnected

7. Wiring Diagrams

The following diagrams are general use cases. Installers are reminded that adherence to local electrical codes and regulations is mandatory. While these diagrams

offer general guidance, they may not encompass all variations and specifics required by local codes. Consult with relevant authorities and ensure compliance before

proceeding with any installation. The diagrams presented herein are not exhaustive and should not be relied upon solely for permitting or warranty verification.

Installers are encouraged to exercise caution, seek professional advice when necessary, and undertake installations with due diligence and in accordance with

established electrical standards and regulations.

Sol-Ark 30K-3P-208V

Standard Wiring Diagram

Diagram 01

Sol-Ark 30K-3P-208V

Standard Wiring Diagram – Off Grid

Diagram 02

Sol-Ark 30K-3P-208V

Standard Wiring Diagram – AC Coupling

Diagram 03

Sol-Ark 30K-3P-208V

Standard Wiring Diagram – Bypass Transfer Switch

Diagram 04

Sol-Ark 30K-3P-208V

Standard Wiring Diagram – Standby Generator

Diagram 05

Diagram 06

Sol-Ark 30K-3P-208V

Standard Wiring Diagram – Grid-Tide Only with Standby Generator

Sol-Ark 30K-3P-208V

Standard Wiring Diagram – 2 Parallel Inverters, Standard Wiring

Diagram 07

Before powering up Parallel System installs, please see section 5 “Parallel Systems”

Diagram 08

Before powering up Parallel System installs, please see section 5 “Parallel Systems”

Sol-Ark 30K-3P-208V

Standard Wiring Diagram – 3 Parallel Inverters, Standard Wiring

8. Troubleshooting Guide

LCD is not powering on

- Check all connections – at least one of the following power sources is required: PV/Grid/Battery

- Try pressing the power button, touchscreen, or navigation buttons

Panels are connected, but “DC” LED indicator is not on

- Startup voltage is 150V. Voltage must be above 150V and below 500V

- Wrong polarity. Check string polarity on MPPT

- PV DC disconnect switches are not on the ON position

Panels are not producing

- Check for proper wiring on all solar panel connections

- Turn PV disconnect switches "ON"

- Check that the PV input voltage is not greater than 550V

- If the system measures 0V even when PV DC disconnect is ON, polarity might be wrong. Check PV polarity

Panels are not producing much power

- PV Wire Strip Length: 5/8". Your batteries are charged and is limited to house loads; you can test Grid Sell to verify.

The system does not keep batteries charged

- Verify there is proper communication between the Sol-Ark and the battery. : → Li-Batt Info

- Verify proper Charge and Voltage settings according to battery manufacturer and battery bank arrangement

Auto Gen-Start is not working

- Make sure the generator has a compatible Two-Wire

- Verify adequate connection to the Sol-Ark auto-start input pins

“Normal” LED indicator is not on

- Sol-Ark is in pass-through mode (only Grid connection and no other power source)

- Not fully energized (DC Solar panels AND Grid or batteries only)

- In alarm state.

- Sol-Ark is not working correctly (Call technical support +1 (972) 575-8875 Ext. 2)

The “Alarm” LED indicator is on

- Check the system alarms menu to identify the alarm

Grid HM value is negative when it should be positive (only applies in Limited to Home mode)

- Limiter Sensors are backwards, L1/L2/L3 sensors are swapped, or incorrectly wired. Execute the "Auto Learn Home Limit Sensors"

command described in section 2.9 "Limit Sensors, Automatic CT Limit Sensors Configuration"

AC Overload Fault or Bus Unbalance Fault

- Check Transfer Switch/Subpanel wiring

- Check for large loads that consume more than the inverter rating

The system connects to grid and quickly disconnects

- Verify Neutral wire connection (0Vac referenced to GND)

- Check the programmed frequency, and verify the Sol-Ark measures 120V between L and N

- If the system is overloading: verify that proper phase sequence between “GRID” and “LOAD” terminals

DC Overload Fault

- Check PV voltage. Ensure no more than 550V

- Make sure you have not wired more than two (2) solar strings in parallel per MPPT

System is beeping

- Check the System Alarms menu to see which alarm has been triggered. Most alarms will self-reset

- Do a Power Cycle as described in section 2.12 “Power Cycle Sequence”

Battery cable sparks when connected

- If applicable, flip the built-in breakers of the battery bank before connecting or disconnecting batteries

Battery symbol on the home screen is red

- The battery is below the empty voltage

- Battery is over-voltage or under-voltage

Battery symbol on the home screen is yellow

- The battery is low, or the charge/discharge current is close to the programmed limit

Grid symbol on the home screen is yellow

- Grid parameters are out of specified operating range

- There is a grid outage and there is no voltage on the “GRID” terminal

- System is Off-Grid

System has restarted

- Occurs when the system has overloaded, battery voltage has surpassed 500V

- There was a Software update

Batteries were connected backwards

- System will be damaged, and warranty will be lost

Why is the LCD screen still on when the power button is off?

- Occurs when the power button is in the “OFF” position

- Occurs when the system is not fully energized: PV or Grid only

The Batt SOC% is not reaching 100%

- BMS communication is not working properly. Verify with battery integration and communication steps

Generator setup is reading 0Hz

- Generator is operating at a frequency outside the permissible range. Select " General Standard " grid mode. Widen the frequency

range to 55Hz-65Hz as described in section 2.5 “Integrating a Generator”

Color Touchscreen is Frozen

- Press and hold the escape button [◄] for 7-10 seconds

- Perform a power cycle sequence in case the above suggestion does not work. See section 2.12 “Power Cycle Sequence”

Grid Phase Wrong

- If the Sol-Ark screen shows a “Grid Phase Wrong” message, it means there is a phasing issue in the wiring. If left unchecked it

may cause overload faults and DAMAGE. See section 5.3 “Troubleshooting Phase Sequence”

8.1 Sol-Ark Error codes

FAULT

INSTRUCTION

COMMON CAUSE / REMEDY

F1

DC_Inversed_Failure

If you have parallel systems and turn one system off, you will get this notification. NOT a fault.

F8

GFDI_Relay_Failure

Check for continuity on the inverter's neutral and ground. Ensure there is only ONE neutral-to-ground

bond in the system. Current Leakage from inverter AC output to Ground, check Ground and neutral are

connected at the main panel.

F13

Grid_Mode_change

It can happen when not using batteries or if Grid Input settings are changed. This is a notification, NOT

a fault. If you switch from No Batt to Battery mode, power the system down completely to restart.

F15

AC_OverCurr_Failure

It is usually caused by Loads too large for the inverter. If Off-Grid, the battery discharge Amps are

programmed too low. Overloads can result in F15, F18, F20, or F26.

F16

GFCI_Failure

Ground fault. Check PV+ or PV- wiring (which must be ungrounded). Exposed PV conductors + rain can

also cause. Check that the neutral line and Ground are not double-bonded (common with portable

generators).

F18

Tz_AC_OverCurr_Fault

Overloaded the Load Output (reduce loads) or overloaded a generator (reduce Gen Start A). Wiring

Short on the AC Side can also cause this error. Overloads can result in F15, F18, F20, or F26.

F20

Tz_Dc_OverCurr_Fault

It is typically caused by DC current from the battery that is too large (ex: 4 Ton AC Unit) or too much PV

current (3 or more strings in parallel). Overloads can result in F15, F18, F20, or F26.

F22

Tz_EmergStop_Fault

Initiated Emergency Stop; see sensor pinout table.

F24

DC_Insulation_Fault

An exposed PV conductor combined with moisture is faulting (can cause F16, F24, and F26).

F25

DC_Feedback_Fault

No battery connection to the Inverter and Activate Battery is enabled. Disable Activate Battery in settings

while no battery is connected.

F26

BusUnbalance_Fault

Too much load on one leg (L1 or L2) vs. the other leg or DC loads on the AC output when Off-Grid.

Grounded PV+/- wire can cause F20, F23, or F26.

F29

Parallel_CANBus_Fault

Usually, a communication error for parallel systems. Check cables, and MODBUS addresses.

F31

Soft_Start_Failed

Soft Start of the large motor failed.

F34

AC_Overload_Fault

AC Overload or load shorted. Reduce heavy loads.

F35

AC_NoUtility_Fault

Grid connection lost.

F37

DCLLC_Soft_Over_Cur

Software DC overcurrent.

F39

DCLLC_Over_Current

Hardware DC overcurrent.

F40

Batt_Over_Current

Batteries exceeded their current discharge limit.

F41

Parallel_System_Stop_Fault

If one system faults in parallel, this normal fault will register on the other units as they disconnect from

the grid.

F45

AC_UV_OverVolt_Fault

Grid under voltage causes a disconnect. This will self-reset when the grid stabilizes.

F46

Battery_Backup_Fault

Cannot communicate with other parallel systems. Check Master = 1, Slaves = 2-9 and that ethernet are

connected.

F47

AC_OverFreq_Fault

Grid over Frequency (common in power outages) causes disconnect. Will self-reset when grid stabilizes.

F48

AC_UnderFreq_Fault

Grid under Frequency (common in power outages) causes a disconnect. Will self-reset when grid

stabilizes.

F55

DC_VoltHigh_Fault

PV may be higher than 500V. Battery voltage should not be above 59V or 63V (depending on the

model).

F56

DC_VoltLow_Fault

Batteries are overly discharged, the inverter is Off-Grid and exceeded the programmed batt discharge

current by 20%, or Lithium BMS has shut down. If battery settings are incorrect, this can also happen.

F58

BMS_Communication Fault

Sol-Ark is programmed to BMS Lithium Battery Mode but cannot communicate with a BMS.

BMS_Err_Stop is enabled, but cannot communicate with a battery BMS

F60

Gen_Volt_or_Fre_Fault

Generator Voltage or Frequency went outside the allowable range.

F61

Button_Manual_OFF

The parallel Slave system turned off without turning off the Master.

F63

Arc_Fault

It can be a poor PV connector / Connection. Or sometimes a false alarm due to powerful lighting storms.

F64

Heatsink_HighTemp_Fault

Check that the built-in fans are running; the ambient temperature may be too high. Ensure proper

clearance.

9. Warranty Verification Checklist

MUST complete this form AFTER the system is operational. To register the product warranty, this verification checklist

must be filled out and submitted to Sol-Ark. Visit https://www.sol-ark.com/register-your-sol-ark/ to register warranty.

Installer/Company:___________________________________ Date: (YYYY-MM-DD) __________________________________

Inverter SN: _________________________________________ Gateway SN:_________________________________________

Mark ✓ for all that apply

Indicate the type of system (all that apply):

 Grid-Tied only

 Grid-Tied with battery backup

 Off-Grid

 Parallel system: # inverters

Indicate integrated components (all that apply):

 Utility grid

 DC solar panels

 AC coupled solar panels

 Generator

 “LOAD” installed service panel

 “GRID” installed service panel

 “GEN” installed service panel

 Lithium batteries

 Lead-Acid batteries

 Wind Turbine

It is strongly recommended to send a Wiring Diagram of the installation to [email protected] for verification, otherwise Sol-Ark

expressly disclaims any responsibility for performance issues arising from improper installation. Installers and users are solely responsible

for following proper installation procedures outlined in provided documentation. Sol-Ark disclaims any liability for changes in the installation

that might result in electrical malfunctions or any other issues related to the Sol-Ark product.

Circle N/A (Not Applicable) if the verification step is not relevant to the type of system or does not apply to the integrated components.

1. A wiring diagram of the installation was sent to Sol-Ark for verification

 Y  N

2. Setup for remote system monitoring through Wi-Fi / Ethernet is completed. Gateway SN:_______________________

 Y  N

3. The inverter is installed in a location where the LCD screen is always protected from direct sunlight



4. The inverter has the minimum specified vertical and lateral clearance for proper heat dissipation



5. The maximum DC input voltage does not surpass 550V

DC



6. The HV Battery bank does not surpass 500V

DC



7. All battery conductors are properly connected and secured to the (+, -) terminals of the inverter

 N/A

8. Battery communication was successfully established

 N/A

9. All Battery Setup parameters are programmed according to battery manufacturer specifications

 N/A

10. The Sol-Ark properly generates power from the solar panels to charge the batteries

 N/A

11. Grid / Generator is properly connected to the Sol-Ark and the phase sequence was verified

 N/A

12. “🗹 Grid / Gen Charge” settings are programmed correctly. Grid / Generator adequately charge the batteries

 N/A

13. For Off-Grid systems: The mode “General Standard” is programmed and the V & f ranges are increased

 N/A

14. When “🗹 Grid Sell” is enabled, the Sol-Ark sells power back to the grid (negative HM measurements for L1, L2, L3)

 N/A

15. Limit sensors are correctly installed on Grid lines / Generator lines

 N/A

16. Only when “🗹 Limited Power to Home” is enabled, the Sol-Ark matches total load demand (Meter Zero)

 N/A

17. Disconnect the grid: during Off-Grid operation, the inverter properly supplies “LOAD” demand for PV and batteries

 N/A

18. Disconnect the grid AND solar panels: during Off-Grid operation, the inverter properly draws power from batteries

 N/A

In the event of system-related issues, forward a comprehensive description of the problem via email to [email protected]. Ensure the

addition of images, including the "Details Screen" with all electrical measurements, as well as images of the inverter, wiring configuration,

user area, batteries, and any other integral components constituting the power system.

______________________________________

Installer name and signature

Customer name and signature

Date

Limited Warranty: Sol-Ark 30K-3P-208V

10-Year Limited Warranty for Sol-Ark LLC Products. Sol-Ark LLC provides a Ten-year (10) limited

Warranty ("Warranty") against defects in materials and workmanship for its Sol-Ark LLC products

("Product"). The term of this warranty begins on the Product(s) initial purchase date, or the date

of receipt of the Product(s) by the end user, whichever is later. This must be indicated on the

invoice, bill of sale from your installer. This warranty applies to the original Sol-Ark LLC Product

purchaser and is transferable only if the Product remains installed in the original use location.

Please call Sol-Ark LLC to let us know if you are selling your Home and give us name and contact

of the new owner.

The warranty does not apply to any Product or Product part that has been modified or damaged by the following:

• Installation or Removal (examples: wrong voltage batteries, connecting batteries backward, damage due to water/rain to

electronics, preventable damage to solar wires.)

• Alteration or Disassembly.

• Normal Wear and Tear.

• Accident or Abuse.

• Unauthorized Firmware updates/software updates or alterations to the software code.

• Corrosion.

• Lightning: unless using EMP hardened system, then Sol-Ark LLC will repair the product.

• Repair or service provided by an unauthorized repair facility.

• Operation or installation contrary to manufacturer product instructions.

• Fire, Floods, or Acts of Nature.

• Shipping or Transportation.

• Incidental or consequential damage caused by other components of the power system.

• Any product whose serial number has been altered, defaced, or removed.

• Any other event not foreseeable by Sol-Ark LLC

Sol-Ark LLC liability for any defective Product, or any Product part, shall be limited to the repair or replacement of the Product, at Sol-Ark

LLC discretion. Sol-Ark LLC does not warrant or guarantee workmanship performed by any person or firm installing its Products. This warranty

does not cover the costs of installation, removal, shipping (except as described below), or reinstallation of Products or parts of Products. LCD

screen and fans are covered for 5 years from date of purchase.

THIS LIMITED WARRANTY IS THE EXCLUSIVE WARRANTY APPLICABLE TO SOL-ARK LLC PRODUCTS. SOL-ARK LLC EXPRESSLY DISCLAIMS

ANY OTHER EXPRESS OR IMPLIED WARRANTIES OF ITS PRODUCTS. SOL-ARK LLC ALSO EXPRESSLY LIMITS ITS LIABILITY IN THE EVENT

OF A PRODUCT DEFECT TO REPAIR OR REPLACEMENT IN ACCORDANCE WITH THE TERMS OF THIS LIMITED WARRANTY AND

EXCLUDES ALL LIABILITY FOR INCIDENTAL OR CONSEQUENTIAL DAMAGES, INCLUDING WITHOUT LIMITATION ANY LIABILITY FOR

PRODUCTS NOT BEING AVAILABLE FOR USE OR LOST REVENUES OR PROFITS, EVEN IF IT IS MADE AWARE OF SUCH POTENTIAL

DAMAGES.

Return Policy - No returns will be accepted without prior authorization and must include the Return Material Authorization (RMA) number.

Please call and talk to one of our engineers to obtain this number at 972-575-8875.

Return Material Authorization (RMA) A request for an RMA number requires all the following information: 1. Product model and serial

number; 2. Proof-of-purchase in the form of a copy of the original Product purchase invoice or receipt confirming the Product model number

and serial number; 3. Description of the problem; 4. Validation of problem by Technical Support, and 5. Shipping address for the repaired

or replacement equipment. Upon receiving this information, the Sol-Ark LLC representative can issue an RMA number. Any product that is

returned must be brand new, in excellent condition and packaged in the original manufacturer's carton with all corresponding hardware

and documentation. Returns must be shipped with prepaid freight and insured via the carrier of your choice to arrive back at Sol-Ark LLC

within 30 days of your initial delivery or pick-up. Shipping charges will not be refunded. All returns are subject to a 35% restocking fee. No

returns will be accepted beyond 30 days of original delivery. The value and cost of replacing any items missing (parts, manuals, etc.) will be

deducted from the refund. If you have any questions regarding our return policy, please email us at [email protected] or call us at the

number above during regular (Monday to Friday) business hours.

Sol-Ark 30K-3P-208V Install Operational Verification Checklist Questionnaire must be filled out, signed, and dated to secure full warranty

coverage.

Contact: (USA) +1-972-575-8875

For Info/Purchasing:

[email protected]om | ext.1

For Tech Support/Warranty Claim:

support@sol-ark.com | ext.2

For Administrative Help | ext.3

10. GUI Screens

1. Main Menu

2. Basic Setup

3. Batt Setup

4. Limiter

5. Grid Setup

Briggs & Stratton 30K-3P-208V Sol-Ark Commercial Hybrid Inverter

Product's Documents

Installation Manual

Specifications

Briggs & Stratton 30K-3P-208V Questions and Answers