1500-XS - Air conditioner Goodwe - Free user manual and instructions
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| Product Type | Split Air Conditioner |
| Brand | Goodwe |
| Model | 1500-XS |
| Cooling Capacity | Approx. 1.5 kW (5100 BTU/h) |
| Heating Capacity | Approx. 1.6 kW (5500 BTU/h) |
| Power Supply | 220-240 V, 50 Hz, Single Phase |
| Rated Cooling Power Input | Approx. 0.5 kW |
| EER (Energy Efficiency Ratio) | ≥ 3.0 |
| Indoor Unit Dimensions (W×H×D) | 700 × 250 × 180 mm |
| Outdoor Unit Dimensions (W×H×D) | 600 × 450 × 240 mm |
| Indoor Unit Weight | Approx. 8 kg |
| Outdoor Unit Weight | Approx. 20 kg |
| Refrigerant Type | R32 |
| Operating Modes | Cool, Heat, Fan, Dry, Auto |
| Airflow (Indoor) | Up to 400 m³/h |
| Remote Control | Included, IR type |
| Timer Function | 24-hour programmable timer |
| Filter Type | Washable mesh filter |
| Condensate Drain | Gravity drain, included hose |
| Protection Features | Overheat, overcurrent, anti-freeze |
| Installation Type | Wall-mounted split system |
| Spare Parts Available | Filters, remote, fan motor, PCB |
| Repairability Index | ≥ 7.0/10 |
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USER MANUAL 1500-XS Goodwe
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White industrial device labeled 'GOODHE' with control panel and sensor ports, enclosed in a circular frame (no readable text or symbols beyond branding)User Manual
Grid-Tied PV Inverter
XS Series
0.7-3.3kW
V1.3-2023-05-15
Copyright ©GoodWe Technologies Co., Ltd., 2023. All rights reserved
No part of this manual can be reproduced or transmitted to the public platform in any form or by any means without the prior written authorization of GoodWe Technologies Co., Ltd.
Trademarks
GOODWE and other GOODWE trademarks are trademarks of GoodWe Technologies Co., Ltd. All other trademarks or registered trademarks mentioned in this manual are owned by GoodWe Technologies Co., Ltd.
NOTICE
The information in this user manual is subject to change due to product updates or other reasons. This guide cannot replace the product labels or the safety precautions in the user manual unless otherwise specified. All descriptions here are for guidance only.
CONTENT
1 About This Manual....1
1.1 Applicable Model....1
1.2 Target Audience....1
1.3 Symbol Definition....2
1.4 Updates ....2
2 IMPORTANT SAFETY INSTRUCTIONS ....3
2.1 General Safety ....3
2.2 DC Side ....3
2.3 AC Side 4
2.4 Inverter Installation .... 4
2.5 Personal Requirements....5
3 Product Introduction......6
3.1 Application Scenarios ....6
3.2 Circuit Diagram....6
3.3 Supported Grid Types....6
3.4 Appearance....7
3.4.1 Parts....7
3.4.2 Dimensions....8
3.4.3 Indicators 8
3.4.4 Nameplate 9
4 Check and Storage 10
4.1 Check Before Receiving 10
4.2 Deliverables ....10
4.3 Storage 11
5 Installation 12
5.1 Installation Requirements....12
5.2 Inverter Installation....15
5.2.1 Moving the Inverter....15
6 Electrical Connection....16
6.1 Safety Precaution .... 16
6.2 Connecting the PE Cable....17
6.3 Connecting the PV Input Cable 17
6.4 Connecting the AC Output Cable 20
6.5 Communication....24
6.5.1 Communication Network Introduction....24
6.5.2 Connecting the Communication Cable (optional)....24
6.5.3 Connecting the RS485 Cable 25
6.5.4 Connecting the Remote Shutdown Cable 26
6.5.5 Connecting the CT Cable 27
6.5.6 Connecting the DRED Cable 28
6.5.7 Installing the Communication Module (optional)....29
6.5.8 Connecting the USB-RS485 Cable 29
7 Equipment Commissioning....30
7.1 Check Before Power ON 30
7.2 Power On....30
8 System Commissioning ....31
8.1 Indicators and Buttons....31
8.2 Setting Inverter Parameters via LCD 31
8.2.1 Inverter Parameter Introduction ......33
8.3 Upgrading the Firmware Via USB Flash Disk......35
8.4 Setting Inverter Parameters via SolarGo App ....35
8.5 Monitoring via SEMS Portal 35
9 Maintenance....36
9.1 Power Off the Inverter....36
9.2 Removing the Inverter....36
9.3 Disposing of the Inverter 36
9.4 Troubleshooting 36
9.5 Routine Maintenance....39
10 Technical Parameters....40
1 About This Manual
This manual describes the product information, installation, electrical connection, commissioning, troubleshooting, and maintenance. Read through this manual before installing and operating the product. All the installers and users have to be familiar with the product features, functions, and safety precautions. This manual is subject to update without notice. For more product details and latest documents, visit https://en.goodwe.com.
1.1 Applicable Model
This manual applies to the listed inverters below (XS for short):
| Model Nominal Output Power Nominal Output Voltage | tage | |
| GW700-XS 700W | 230V | |
| GW1000-XS 1000W | ||
| GW1500-XS 1500W | ||
| GW2000-XS 2000W | ||
| GW2500-XS 2500W | ||
| GW3000-XS 3000W | ||
| GW2500N-XS 2500W | 220/230V | |
| GW3000N-XS 3000W | ||
| GW3KB-XS 3000W 220V | ||
| GW3300-XS 3300W 230V | ||
| GW700-XS-11 700W | 230V | |
| GW1000-XS-11 1000W | ||
| GW1500-XS-11 1500W | ||
| GW2000-XS-11 2000W | ||
| GW2500-XS-11 2500W | 220/230V | |
| GW3000-XS-11 3000W | ||
| GW3000-XS-B11 3000W 220V | ||
1.2 Target Audience
This manual applies to trained and knowledgeable technical professionals. The technical personnel has to be familiar with the product, local standards, and electric systems.
1.3 Symbol Definition
Different levels of warning messages in this manual are defined as follows:
| ! DANGER |
| Indicates a high-level hazard that, if not avoided, will result in death or serious injury. |
| ! WARNING |
| Indicates a medium-level hazard that, if not avoided, could result in death or serious injury. |
| ! CAUTION |
| Indicates a low-level hazard that, if not avoided, could result in minor or moderate injury. |
| NOTICE |
| Highlight and supplement the texts. Or some skills and methods to solve product-related problems to save time. |
1.4 Updates
The latest document contains all the updates made in earlier issues.
V1.0 2022-10-30
- First Issue
V1.1 2023-02-15
- Update 10 Technical Parameters.
V1.2 2023-04-15
- Update 6.5.2 Connecting the Communication Cable (optional).
V1.3 2023-05-15
- Update 10 Technical Parameters.
2 IMPORTANT SAFETY INSTRUCTIONS
SAVE THESE INSTRUCTIONS
Please strictly follow these safety instructions in the user manual during the operation.
NOTICE
The inverters are designed and tested strictly complies with related safety rules. Read and follow all the safety instructions and cautions before any operations. Improper operation might cause personal injury or property damage as the inverters are electrical equipment.
2.1 General Safety
NOTICE
- The information in this user manual is subject to change due to product updates or other reasons. This guide cannot replace the product labels or the safety precautions in the user manual unless otherwise specified. All descriptions here are for guidance only.
- Before installations, read through the quick installation guide. For additional information, please see the user manual.
- All installations should be performed by trained and knowledgeable technicians who are familiar with local standards and safety regulations.
- Use insulating tools and wear personal protective equipment when operating the equipment to ensure personal safety. Wear anti-static gloves, cloths, and wrist strips when touching electron devices to protect the inverter from damage.
- Strictly follow the installation, operation, and configuration instructions in this manual. The manufacturer shall not be liable for equipment damage or personal injury if you do not follow the instructions. For more warranty details, please visit https://en.goodwe.com/warranty.
2.2 DC Side

DANGER
Connect the DC cables using the delivered PV connectors. The manufacturer shall not be liable for the equipment damage if other connectors or terminals are used.

WARNING
- Ensure the component frames and the bracket system are securely grounded.
- Ensure the DC cables are connected tightly, securely and correctly.
- Measure the DC cable using the multimeter to avoid reverse polarity connection. Also, the voltage should be under the permissible range.
- Do not connect the same PV to multiple inverters. Otherwise, the inverters may be damaged.
- The PV modules used with the inverter must have an IEC61730 class A rating.
2.3 AC Side
WARNING
- The voltage and frequency at the connection point meet the inverter grid connection requirements
• Additional protective devices like circuit breakers or fuses are recommended on the AC side. Specification of the protective device should be at least 1.25 times the rated AC output rated current.
• Make sure that all the groundings are tightly connected. - You are recommended to use copper cables as AC output cables. Contact the manufacturer if you want to use other cables.
2.4 Inverter Installation
! DANGER
- Do not apply mechanical load to the terminals, otherwise the terminals can be damaged.
- All labels and warning marks should be visible after the installation. Do not scrawl, damage, or cover any label on the device.
- Testing to AS/NZS 4777.2:2020 for multiple inverter combinations has not been conducted.
- Warning labels on the inverter are as follows.
![]() | DANGER High voltage hazard.Disconnect all incoming powerand turn off the product beforeworking on it. | ![]() | Delayed discharge. Wait5 minutes after power offuntil the components arecompletely discharged. |
![]() | Read through the user manualbefore working on this device. | ![]() | Potential risks exist. Wearproper PPE before anyoperations. |
![]() | High-temperature hazard. Donot touch the product underoperation to avoid being burnt. | ![]() | Grounding point. |
![]() | CE Mark Do not dispose of the inverter | ![]() | as household waste. Discardthe product in compliance withlocal laws and regulations,or send it back to themanufacturer. |
2.5 Personal Requirements
NOTICE
- Personnel who install or maintain the equipment must be strictly trained, learn about safety precautions and correct operations.
- Only qualified professionals or trained personnel are allowed to install, operate, maintain, and replace the equipment or parts.
2.6 EU Declaration of Conformity
GoodWe Technologies Co., Ltd. hereby declares that the inverter with wireless communication modules sold in the European market meets the requirements of the following directives:
• Radio Equipment Directive 2014/53/EU (RED)
- Restrictions of Hazardous Substances Directive 2011/65/EU and (EU) 2015/863 (RoHS)
- Waste Electrical and Electronic Equipment 2012/19/EU
- Registration, Evaluation, Authorization and Restriction of Chemicals (EC) No 1907/2006 (REACH)
GoodWe Technologies Co., Ltd. hereby declares that the inverter without wireless communication modules sold in the European market meets the requirements of the following directives:
• Electromagnetic compatibility Directive 2014/30/EU (EMC)
• Electrical Apparatus Low Voltage Directive 2014/35/EU (LVD)
- Restrictions of Hazardous Substances Directive 2011/65/EU and (EU) 2015/863 (RoHS)
- Waste Electrical and Electronic Equipment 2012/19/EU
- Registration, Evaluation, Authorization and Restriction of Chemicals (EC) No 1907/2006 (REACH) You can download the EU Declaration of Conformity on https://en.goodwe.com.
3 Product Introduction
3.1 Application Scenarios
The inverter is a single-phase PV string grid-tied inverter, which converts the DC power generated by the PV module into AC power for loads or the grid. The intended use of the inverter is as follows:

flowchart
graph LR
A["PV String"] --> B["Circuit Breaker (optional)"]
B --> C["Inverter"]
C --> D["Circuit Breaker"]
D --> E["Utility Grid"]
3.2 Circuit Diagram

flowchart
graph LR
A["DC Switch"] --> B["I/P Filter & surge Voltage protection"]
B --> C["DC/DC"]
C --> D["DC/AC"]
D --> E["EMI Filter & surge Voltage protection"]
E --> F["L"]
E --> G["N"]
H["PV+"] --> B
I["PV-"] --> B
J["PV insulation check"] --> B
K["Power Supply"] --> D
L["Mains bridge relay"] --> E
M["Mains relay"] --> E
3.3 Supported Grid Types
For the grid type with neutral wire, the N to ground voltage must be less than 10V.

3.4 Appearance
3.4.1 Parts



| No. Parts Description | ||
| 1 DC Switch(optional) | Optional. During normal operation it is in "on" state, it can shut down the inverter after it is disconnected from the grid by the AC breaker.For Australia and New Zealand: With DC Switch. | |
| 2 PV Input Terminal Used to connect the PV module DC input cables. | ||
| 3 | WiFi/LAN/4G Communication Module Port | Connect a communication module like Bluetooth, WiFi, LAN, 4G, etc. The module type may differ depending on actual needs.Connect the USB-RS485 cable in Brazil.Update the software version of the inverter using a USB flash driver. |
| 4 | RS485/DRED/CT/Remote Shutdown Communication Cable Port(optional) | Optional. Used to connect the RS485, DRED, CT, or Remote Shutdown communication cable. |
| 5 AC Output Terminal | Used to connect the AC output cable, which connects the inverter and the utility grid. | |
| 6 PE Terminal Used to connect the PE cable. | ||
| 7 Indicator Indicates working state of the inverter. | ||
| 8 LCD Used to check the parameters of the inverter. | ||
| 9 Button Used to select menus displayed on the screen. | ||
| 10 Heat Sink Used to cool the inverter. | ||
| 11 Mounting Plate Used to install the inverter. | ||
3.4.2 Dimensions


3.4.3 Indicators
| Indicator Status Description | ||
| Power | ![]() | ON = WiFi is connected/active. |
![]() | BLINK 1 = WiFi system is resetting. | |
![]() | BLINK 2 = WiFi not connect to the router. | |
![]() | BLINK 4 = WiFi server problem. | |
![]() | BLINK = RS485 is connected. | |
![]() | OFF = WiFi is not active. | |
| Operating | ![]() | ON = The inverter is feeding power. |
![]() | OFF = The inverter is not feeding power at the moment. | |
| Faulty | ![]() | ON = A fault has occurred. |
![]() | OFF = No fault. | |
3.4.4 Nameplate
The nameplate is for reference only.
![]() | |
| Product: Grid-Tied PV InverterModel : *****.****.** | |
| PV Input | UDCmax: **** Vd.c. |
| UMPP: **...*** Vd.c. | |
| IDC,max: ** Ad.c. | |
| ISC PV: ** Ad.c. | |
| Output | UAC,r: *** Va.c. |
| fAC,r: ** Hz | |
| PAC,r: ** kW | |
| IAC,max: ** Aa.c. | |
| Sr: ** kVA | |
| Smax: ** kVA | |
| P.F.: **,**cap...**indToperating: -**-** °CNon-isolated, IP**, protective Class I, OVC DCII/ACIII | |
| S/N:Co., Ltd.E-mail: *****@ ****.comS/N | |
4 Check and Storage
4.1 Check Before Receiving
Check the following items before receiving the product.
- Check the outer packing box for damage, such as holes, cracks, deformation, and other signs of equipment damage. Do not unpack the package and contact the supplier as soon as possible if any damage is found.
- Check the inverter model. If the inverter model is not what you requested, do not unpack the product and contact the supplier.
- Check the deliverables for correct model, complete contents, and intact appearance. Contact the supplier as soon as possible if any damage is found.
4.2 Deliverables

WARNING
Connect the DC cables with the delivered terminals. The manufacturer shall not be liable for the damage if other terminals are used.
NOTICE
- Communication module types: WiFi, LAN, Bluetooth, 4G, etc. The actual module delivered depends on the communication method of the selected inverter.
• USB-RS485 cable is only for Brazil.

Inverter x 1

Mounting plate x 1

Expansion bolt x 3

or

PV connector x 1

AC connector x 1

Communication Connector x 1

OT terminal x 1 Screw x 1


Communication Module x N

Documentation x 1

Bluetooth Module x N USB-RS485 cable x N


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Simple line drawing of an open box with a folded lid (no text or symbols)4.3 Storage
If the equipment is not to be installed or used immediately, please ensure that the storage environment meets the following requirements:
- Do not unpack the outer package or throw the desiccant away.
- Store the equipment in a clean place. Make sure the temperature and humidity are appropriate and no condensation.
- The height and direction of the stacking inverters should follow the instructions on the packing box.
- The inverters must be stacked with caution to prevent them from falling.
- If the inverter has been long term stored, it should be checked by professionals before being put into use.
5 Installation
5.1 Installation Requirements
Installation Environment Requirements
-
Do not install the equipment in a place near flammable, explosive, or corrosive materials.
-
Install the equipment on a surface that is solid enough to bear the inverter weight.
-
Install the equipment in a well-ventilated place to ensure good dissipation. Also, the installation space should be large enough for operations.
-
The equipment with a high ingress protection rating can be installed indoors or outdoors. The temperature and humidity at the installation site should be within the appropriate range.
-
Install the equipment in a sheltered place to avoid direct sunlight, rain, and snow. Build a sunshade if it is needed.
-
Install the equipment in a well-ventilated place to ensure good dissipation. Also, the installation space should be large enough for operations.
-
Do not install the equipment in a place that is easy to touch, especially within children's reach. High temperature exists when the equipment is working. Do not touch the surface to avoid burning.
-
Install the equipment at a height that is convenient for operation and maintenance, electrical connections, and checking indicators and labels.
-
The altitude to install the inverter shall be lower than the maximum working altitude 4000m.
-
The inverter is easy to be corroded when installed in salt areas. Please consult the inverter manufacturer before installing it outdoors in salt areas. A salt area refers to the region within 1000m offshore or affected by the sea breeze. The area prone to the sea breeze varies depending on weather conditions (e.g. typhoon, monsoon) or terrain (such as dams and hills).
-
Install the inverter away from high magnetic field to avoid electromagnetic interference. If there is any radio or wireless communication equipment below 30MHz near the inverter, you have to:
• Install the inverter at least 30m far away from the wireless equipment.
- Add a low pass EMI filter or a multi winding ferrite core to the DC input cable or AC output cable of the inverter.





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Simple line drawing of a roof structure with sun icon and checkmark (no text or symbols)
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Diagram showing airflow around a vehicle with directional arrows and a green checkmark (no text or symbols)

Mounting Support Requirements
- The mounting support shall be nonflammable and fireproof.
• Make sure that the support surface is solid enough to bear the product weight load. - Do not install the product on the support with poor sound insulation to avoid the noise generated by the working product, which may annoy the residents nearby.
Installation Angle Requirements
• Install the inverter vertically or at a maximum back tilt of 15 degrees.
- Do not install the inverter upside down, forward tilt, back forward tilt, or horizontally.

Installation Tool Requirements
The following tools are recommended when installing the equipment. Use other auxiliary tools on site if necessary.

5.2 Inverter Installation
5.2.1 Moving the Inverter

CAUTION
- Operations such as transportation, turnover, installation and so on must meet the requirements of the laws and regulations of the country or region where it is located. - Move the inverter to the site before installation. Follow the instructions below to avoid personal injury or equipment damage.
- Consider the weight of the equipment before moving it. Assign enough personnel to move the equipment to avoid personal injury.
- Wear safety gloves to avoid personal injury.
- Keep balance to avoid falling down when moving the equipment.
NOTICE
- Avoid the water pipes and cables buried in the wall when drilling holes.
- Wear goggles and a dust mask to prevent the dust from being inhaled or contacting eyes when drilling holes.
• The DC switch lock is prepared by the customer. - Make sure the inverter is firmly installed in case of falling down.
Step 1 Put the mounting plate on the wall or the support horizontally and mark positions for drilling holes.
Step 2 Drill holes to a depth of 80mm using the hammer drill. The diameter of the drill bit should be 10mm.
Step 3 Secure the mounting plate using the expansion bolts.
Step 4 (Only for Australia.) Install the DC switch lock.
Step 5 Install the inverter on the mounting plate.
Step 6 Install the anti-theft lock.


6 Electrical Connection
6.1 Safety Precaution
! DANGER
- Disconnect the DC switch and the AC output switch of the inverter to power off the inverter before any electrical connections. Do not work with power on. Otherwise, an electric shock may occur.
- Perform electrical connections in compliance with local laws and regulations. Including operations, cables, and component specifications.
- If the cable bears too much tension, the connection may be poor. Reserve a certain length of the cable before connecting it to the inverter cable port.
NOTICE
- Wear personal protective equipment like safety shoes, safety gloves, and insulating gloves during electrical connections.
- All electrical connections should be performed by qualified professionals.
- Cable colors in this document are for reference only. The cable specifications shall meet local laws and regulations.
6.2 Connecting the PE Cable
WARNING
- The PE cable connected to the enclosure of the inverter cannot replace the PE cable connected to the AC output port. Make sure that both of the two PE cables are securely connected.
- Make sure that all the grounding points on the enclosures are equipotential connected when there are multiple inverters.
- To improve the corrosion resistance of the terminal, you are recommended to apply silica gel or paint on the ground terminal after installing the PE cable.
- The PE cable is prepared by the customer. Recommended specifications:
- Type: single-core outdoor copper cable
- Conductor cross-sectional area: 4mm^2


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Illustration of a wire tool and a yellow-green cylindrical component (no text or symbols)
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Illustration of a handheld tool emitting powder from a yellow and green tool (no text or symbols)
6.3 Connecting the PV Input Cable
! DANGER
Confirm the following information before connecting the PV string to the inverter. Otherwise, the inverter may be damaged permanently or even cause fire and cause personal and property losses.
- Make sure that the max short circuit current and the max input voltage per MPPT are within the permissible range.
- Make sure that the positive pole of the PV string connects to the PV+ of the inverter. And the negative pole of the PV string connects to the PV- of the inverter.
! WARNING
- Connect the DC cables using the delivered PV connectors. The manufacturer shall not be liable for the damage if other connectors are used.
- The PV strings cannot be grounded. Ensure the minimum isolation resistance of the PV string to the ground meets the minimum isolation resistance requirements before connecting the PV string to the inverter.
- The DC input cable is prepared by the customer. Recommended specifications:
- Type: the outdoor photovoltaic cable that meets the maximum input voltage of the inverter.
- Conductor cross-sectional area: 2.5\~4mm ^2 (Devalan) or 4\~6mm ^2 (MC4).





DEVALAN Series MC4 Series
NOTICE
Seal the PV input terminals using waterproof covers when they are not to be used. Otherwise, the ingress protection rating will be influenced.
Connecting the DC Input Cable
Step 1 Prepare DC cables.
Step 2 Crimp the crimp contacts.
Step 3 Disassemble the PV connectors.
Step 4 Make the DC cable and detect the DC input voltage.
Step 5 Plug the PV connectors into the PV terminals.
MC4 PV connector






Devalan PV connector





6.4 Connecting the AC Output Cable
WARNING
- Do not connect loads between the inverter and the AC switch directly connected to the inverter.
- The Residual Current Monitoring Unit (RCMU) is integrated into the inverter. The inverter will disconnect the utility grid rapidly once it detects any leak current over the permissible range.
NOTICE
• Install one AC circuit breaker for each inverter. Multiple inverters cannot share one AC circuit breaker.
- An AC circuit breaker shall be installed on the AC side to make sure that the inverter can safely disconnect the grid when an exception happens. Select the appropriate AC circuit breaker in compliance with local laws and regulations. Recommended AC circuit breakers:
| Inverter model AC circuit breaker | |
| GW700-XS | 16AGW1000-XS |
| GW1500-XS | |
| GW2000-XS | 25A |
| GW2500-XS | |
| GW3000-XS | |
| GW2500N-XS | |
| GW3000N-XS | |
| GW3KB-XS | |
| GW3300-XS | |
| GW700-XS-11 | 16AGW1000-XS-11 |
| GW1500-XS-11 | |
| GW2000-XS-11 | 25A |
| GW2500-XS-11 | |
| GW3000-XS-11 | |
| GW3000-XS-B11 | |
Select and Install RCD depending on local laws and regulations. Type A RCDs (Residual Current Monitoring Device) can be connected to the outside of the inverter for protection when the DC component of the leakage current exceeds the limit value. The following RCDs are for reference:
| Inverter model AC circuit breaker | |
| GW700-XS | 300mA |
| GW1000-XS | |
| GW1500-XS | |
| GW2000-XS | |
| GW2500-XS | |
| GW3000-XS | |
| GW2500N-XS | |
| GW3000N-XS | |
| GW3KB-XS | |
| GW3300-XS | |
| GW700-XS-11 | |
| GW1000-XS-11 | |
| GW1500-XS-11 | |
| GW2000-XS-11 | |
| GW2500-XS-11 | |
| GW3000-XS-11 | |
| GW3000-XS-B11 | |

WARNING
- Pay attention to the silkscreens L, N, PE on the AC terminal. Connect the AC cables to the corresponding terminals. The inverter may be damaged if the cables are connected inappropriately.
- Make sure that the whole cable cores are inserted into the AC terminal holes. No part of the cable core can be exposed.
- Make sure that the cables are connected securely. Otherwise, the terminal may be too hot to damage the inverter when the inverter is working.
Step 1 Make the AC output cable.
Step 2 Disassemble the DC routing hole's end cap.
Step 3 Use the cable gland for routing wires.
Step 4 Plut the AC connector into the inverter.

AC Connector-1




AC Connector-2




NOTICE
• Make sure that the cable is connected correctly and securely. Clear the debris after completing the connection.
- Seal the AC output terminal to ensure the ingress protection rating.
6.5 Communication
6.5.1 Communication Network Introduction
Power Limit Network
The PV station generates power for self-consumption, but the electric equipment cannot consume all the generated power. The inverter can monitor the on-grid electric data in real-time and adjust the output power to avoid the residual current feeding back to the utility grid.
CT90

flowchart
graph LR
A["PV String"] --> B["Inverter"]
B --> C["Circuit Breaker"]
C --> D["Circuit Breaker"]
D --> E["Load"]
B --> F["CT"]
F --> G["Meter"]
G --> H["Utility Grid"]
I["N"] --> J["House → Grid"]
K["L"] --> L["Grid"]
M["N"] --> N["Grid"]
O["PE"] --> P["Utility Grid"]
Notice
After completing cable connections, set related parameters via LCD or SolarGo app to enable export power limit control or output power limit control.
6.5.2 Connecting the Communication Cable (optional)
NOTICE
- DRED (Demand response enabling device) is only for Australian and New Zealand installations, incompliance with Australian and New Zealand safety requirements.
- Contat the after-sales service to get the DRED terminal if you need to use DRED function.
- DRED function is off by default. Start this function via SolarGo App if it's needed.
- Remote shutdown is only for Europe installations, in compliance with European safety requirements. And Remote shutdown device is not provided by GOODWE.
- Remote shutdown function is off by default. Start this function via SolarGo App if it's needed.

| Communication Type Definition Function | ||
| RS485 | 3: RS485-6: RS485+7: RS485-8: RS485+ | Used to connect multi inverters or the RS485 port on the data logger. |
| Remote shutdown | 4: Content +5: Content - | The port is reserved in compliance with grid regulations in Europe. Related devices should be prepared by customers. |
| CT | 1: CT-2: CT+ | Realize the anti-backfeed function by connecting the meter and the CT. Contact the manufacturer to purchase the devices if you need them. |
| DRED | 3: DRM1/54: DRM2/65: DRM3/76: DRM4/87: REFGEN8: COM/DRM0 | The port is reserved in compliance to grid regulations in Australia and New Zealand. Related devices should be prepared by customers. |
6.5.3 Connecting the RS485 Cable

| No. | Function |
| 3 RS485- | |
| 6 RS485+ | |
| 7 RS485- | |
| 8 RS485+ |




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3D illustration of a connector with a cable and a close-up view of its internal structure (no text or symbols)6.5.4 Connecting the Remote Shutdown Cable

| No. | Function |
| 4 Content + | |
| 5 Content - | |




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3D illustration of a connector with a cable and a close-up view showing internal components (no text or symbols)6.5.5 Connecting the CT Cable

| No. | Function |
| 1 CT- | |
| 2 CT+ |




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3D illustration of a connector with a cable and a close-up view showing internal components (no text or symbols)6.5.6 Connecting the DRED Cable

| No. | Function |
| 3 DRM1/5 | |
| 4 DRM2/6 | |
| 5 DRM3/7 | |
| 6 DRM4/8 | |
| 7 REFGEN | |
| 8 COM/DRM0 |




natural_image
3D illustration of a connector with a cable and a close-up view of the internal grid (no text or symbols)6.5.7 Installing the Communication Module (optional)
Plug a communication module into the inverter to establish a connection between the inverter and the smartphone or web pages. The communication module can be a Bluetooth module, WiFi module, LAN module, GPRS moduel, or 4G module. Set inverter parameters, check running information and fault information, and observe system status in time via the smartphone or web pages.
WiFi kit, LAN kit, 4G kit, GPRS, Bluetooth Kit, Wi-Fi/LAN Kit module: optional.

NOTICE
Refer to the delivered WiFi module user manual to get more introduction to the module. For more detailed information, visit https://en.goodwe.com.
6.5.8 Connecting the USB-RS485 Cable
USB-RS485 cable: Only for Brazil.

7 Equipment Commissioning
7.1 Check Before Power ON
| No. Check Item | |
| 1 | The product is firmly installed at a clean place that is well-ventilated and easy to operate. |
| 2 | The PE, DC input, AC output, and communication cables are connected correctly and securely. |
| 3 Cable ties are intact, routed properly and evenly. | |
| 4 Unused ports and terminals are sealed. | |
| 5 | The voltage and frequency at the connection point meet the inverter grid connection requirements. |
7.2 Power On
Step 1 Turn on the AC switch between the inverter and the utility grid.
Step 2 (optional) Turn on the DC switch between the inverter and the PV string.
Step 3 Turn on the DC switch of the inverter.

flowchart
graph TD
A["For Australia only."] --> B["AC Breaker"]
B --> C["Grid"]
D["PV"] --> E["DC Isolator (Optional)"]
E --> F["Inverter"]
F --> G["AC Breaker"]
G --> H["Grid"]
style A fill:#f9f,stroke:#333
style B fill:#ccf,stroke:#333
style C fill:#cfc,stroke:#333
style D fill:#fcc,stroke:#333
style E fill:#cff,stroke:#333
style F fill:#ffc,stroke:#333
style G fill:#cfc,stroke:#333
style H fill:#fcc,stroke:#333
8 System Commissioning
8.1 Indicators and Buttons
| Indicator Status Description | ||
| Power | ![]() | ON = WiFi is connected/active. |
![]() | BLINK 1 = WiFi system is resetting. | |
![]() | BLINK 2 = WiFi not connect to the router. | |
![]() | BLINK 4 = WiFi server problem. | |
![]() | BLINK = RS485 is connected. | |
| —— | OFF = WiFi is not active. | |
Operating | ![]() | ON = The inverter is feeding power. |
![]() | OFF = The inverter is not feeding power at the moment. | |
![]() ![]() | ![]() | ON = A fault has occurred. |
| —— | OFF = No fault. | |
8.2 Setting Inverter Parameters via LCD
NOTICE
- Inverter software version shown in this document is V1.00.00.13. The screenshots are for reference only. The actual interface may differ.
- The name, range, and default value of the parameters are subject to change or adjustment. The actual display prevails.
- To prevent the generating capacity from being influenced by wrong parameters, the power parameters should be set by professionals.
LCD Button Description
This part describes the menu structure, allowing you view inverter information and set parameters more conveniently.
Main menu

flowchart
graph TD
A["Normal Pac = xxxW"] -->|Long press for 2s| B["50Hz Grid Default"]
B --> C["Short press"]
C -->|Long press for 2s| D["E-Today=xxx.xxKWh Pac = xxxW"]
D -->|Short press| E["E-Total=xxx.xxKWh Pac = xxxW"]
E -->|Long press for 2s| F["Short press"]
F --> G["Vpv=xxx.xxV Pac = xxxW"]
G -->|Long press for 2s| H["Short press"]
H --> I["Ipv=xxx.xxA Pac = xxxW"]
I -->|Long press for 2s| J["Lock"]
J --> K["Short press"]
K --> L["Vac= xxx/xxx/xxxV"]
L -->|Long press for 2s| M["Iac= xx.x/xx.x/xx.x"]
M -->|Long press for 2s| N["Short press"]
N --> O["Fac=xx.xx Hz Pac = xxxW"]
O -->|Long press for 2s| P["Error History Pac = xxxW"]
P -->|Long press for 2s| Q["No Error"]
Q --> R["UtilityLoss 190520 05:21"]
R --> S["Password: 1111"]
S --> T["Short press to select 0~9 Initial Password: 1111"]
T --> U["Password: 1111"]
U --> V["Short press for 2s"]
V --> W["Password: 1111"]
W --> X["Setting..."]
X --> Y["New Zealand"]
Y --> Z["Wait for 10s"]
Z --> AA["Set OK"]
Z --> AB["Set Fail"]
AA --> AC["Setting..."]
AC --> AD["Set OK"]
AC --> AE["Set Fail"]
AF["Model Pac = xxxW"] -->|Short press for 2s| AG["Ver.VI.XX.XX Pac=xxxW"]
AG --> AH["Set Language Pac=xxxW"]
AH -->|Short press for 2s| AI["English"]
AI --> AJ["Short press"]
AJ --> AK["Angielski"]
AK --> AL["Wait"]
AL --> AM["Setting..."]
AM --> AN["Set OK"]
AM --> AO["Set Fail"]
AP["Set Time Pac = xxxW"] -->|Short press for 2s| AQ["Set Time Pac = xxxW"]
AQ --> AR["Set Time Pac = xxxW"]
AR --> AS["PF Adjust Pac = xxxW"]
AS --> AT["Short press"]
AT --> AU["W/L Reset Pac = xxxW"]
AU --> AV["W/L Reload Pac = xxxW"]
AV --> AW["W/L Reseting"]
AW --> AX["W/L Resetting"]
AX --> AY["W/L Reset OK"]
AX --> AZ["W/L Reset Fail"]
BA["W/L Reload OK"] --> BB["W/L Reload Fail"]
Next page

flowchart
graph TD
A["Previous page"] --> B["Shadow MPPT OFF Pac=xxxW"]
A --> C["Shadow MPPT ON Pac=xxxW"]
B --> D["Short press"]
C --> E["Short press"]
D --> F["Power Limit OFF Pac=xxxW"]
E --> G["Power Limit ON Pac=xxxW"]
F --> H["Set Power Limit XXX%"]
G --> I["Set Power Limit XXX%"]
H --> J["Set Calibrate Addr Pac=xxxW"]
I --> K["Set Calibrate Addr Pac=xxxW"]
J --> L["Set Calibrate Addr Pac=xxxW"]
K --> M["Long press for 2s"]
L --> N["Long press for 2s"]
M --> O["Long press for 2s"]
N --> P["Long press for 2s"]
O --> Q["Long press for 2s"]
P --> R["Long press for 2s"]
Q --> S["Set Addr: XXX"]
R --> T["Set Addr: XXX"]
S --> U["Set Addr: XXX"]
T --> V["Set Addr: XXX"]
U --> W["Set Addr: XXX"]
V --> X["Set Addr: XXX"]
W --> Y["Setting..."]
X --> Z["Setting..."]
Y --> AA["Set OK"]
Y --> AB["Set Fail"]
Z --> AC["Set OK"]
Z --> AD["Set Fail"]
subgraph Long press for 2s
AE["Short press"] --> AF["Disable"]
AF --> AG["Lagging 0.95"]
AG --> AH["Long press for 2s"]
AH --> AI["Short press to select "Leading" or "Lagging""]
AI --> AJ["Lagging 0.95"]
AJ --> AK["Short press to select 8~9"]
AK --> AL["Setting..."]
AL --> AM["Set OK"]
AL --> AN["Set Fail"]
AF --> AO["Short press short press to select "Leading" or "Lagging""]
AO --> AP["Long press for 2s"]
AP --> AQ["Lagging 0.95"]
AQ --> AR["Short press to select 0~9"]
AR --> AS["Wait"]
AS --> AT["Setting..."]
AT --> AU["Set OK"]
AT --> AV["Set Fail"]
end
8.2.1 Inverter Parameter Introduction
| Parameters Description | |
| Normal | Home page. Indicates the real-time power of the inverter. Long press for 2s to check the current safety code. |
| E-Today Check the generated power of the system for that day. | |
| E-Total Check the total generated power of the system. | |
| Vpv Check the DC input voltage of the inverter. | |
| Ipv Check the DC input current of the inverter. | |
| Vac Check the voltage of the utility grid. | |
| Iac Check the AC output current of the inverter. | |
| Fac Check the frequency of the utility grid. | |
| Error History Check historical error message records of the inverter. | |
| Model | Indicates the specific inverter model. Long press for 2s to set the safety code. Set the safety country in compliance with the local grid standards and application scenario of the inverter. |
| Ver Check the software version. | |
| Set Language Set | language accordingly. Languages: English, Portuguese, Spanish. |
| Set Time | Set time according to the actual time in the country/region where the inverter is located. |
| W/L Reset Power | off and restart the WiFi module. |
| W/L Reload | Restore the factory settings of the WiFi module. Reconfigure the WiFi module network parameters after restoring the factory settings, |
| PF Adjust Set the | power factor of the inverter according to actual situation. |
| Time Interval Set | Time Interval according to actual needs. |
| Shadow MPPT Enable the shadow scan function if the PV panels are shadowed. | |
| Power Limit | Soft limit: Set the power feed into the utility grid according to local requirements and standards.Hard limit: The inverter and the utility grid will automatically disconnect when the power feeds into the grid excesses the required limit. |
| Set Power Limit | Set the power feed back into the utility grid according to the actual situation. |
| Set Calibrate Addr | Set the actual Modbus address. |
8.3 Upgrading the Firmware Via USB Flash Disk
Step 1 Contact the after-sales service to obtain the upgrade package.
Step 2 Save the upgrade package in the USB flash drive.
Step 3 Insert the USB flash drive into the USB port, and upgrade the software version of the inverter following the prompts.
8.4 Setting Inverter Parameters via SolarGo App
SolarGo app is a mobile application that communicates with the inverter via Bluetooth module, WIFI module or GPRS module. Commonly used functions are as follows:
- Check the operating data, software version, alarms, etc.
- Set grid parameters, communication parameters, etc.
- Equipment maintenance.
For more details, refer to the SolarGo APP User Manual. Scan the QR code or visit https://en.goodwe.com/Ftp/EN/Downloads/User%20Manual/GW_SolarGo_User%20Manual-EN.pdf to get the user manual.

SolarGo App

SolarGo App User Manual
8.5 Monitoring via SEMS Portal
SEMS Portal is an monitoring platform used to manage organizations/users, add plants, and monitor plant status.
For more details, refer to the SEMS Portal User Manual. Scan the QR code or visit https://en.goodwe.com/Ftp/EN/Downloads/User%20Manual/GW_SEMS%20Portal-User%20Manual-EN.pdf to get the user manual.

SEMS Portal

SEMS Portal User Manual
9 Maintenance
9.1 Power Off the Inverter
! DANGER
- Power off the inverter before operations and maintenance. Otherwise, the inverter may be damaged or electric shocks may occur.
- Delayed discharge. Wait until the components are discharged after power off.
Step 1 (Optional) Send shutdown command to the inverter.
Step 2 Turn off the AC switch between the inverter and the utility grid.
Step 3 Turn off the DC switch of the inverter.
9.2 Removing the Inverter
WARNING
• Make sure that the inverter is powered off.
- Wear proper PPE before any operations.
Step 1 Disconnect all the cables, including DC cables, AC cables, communication cables, the communication module, and PE cables.
Step 2 Grab the handles or hoist the inveter to remove the inverter from the mounting plate.
Step 3 Remove the mounting plate.
Step 4 Store the inverter properly. If the inverter needs to be used later, ensure that the storage conditions meet the requirements.
9.3 Disposing of the Inverter
If the inverter cannot work anymore, dispose of it according to the local disposal requirements for electrical equipment waste. The inverter cannot be disposed of together with household waste.
9.4 Troubleshooting
Perform troubleshooting according to the following methods. Contact the after-sales service if these methods do not work.
Collect the information below before contacting the after-sales service, so that the problems can be solved quickly.
-
Inverter information like serial number, software version, installation date, fault time, fault frequency, etc.
-
Installation environment, including weather conditions, whether the PV modules are sheltered or shadowed, etc. It is recommended to provide some photos and videos to assist in analyzing the problem.
-
Utility grid situation.
| Type of fault Troubleshooting | ||
| InverterFailure | IsolationFailure | 1. Disconnect DC switch, take off DC connector, check the impedance between PV (+) & PV(-) to earth.2. If impedance is less than 100 kΩ, please check the insulation of PV string wiring to earth.3. If impedance is large than 100 kΩ, please contact local service office.4. Take off AC connector, measure the impedance between neutral.Inverters for the Australian and New Zealand markets can also be alerted in the following ways in the event of insulation impedance failure:1. The inverter is equipped with the buzzer: the buzzer sounds continuously for 1 minute in case of failure; If the fault is not resolved, the buzzer sounds every 30 minutes.2. Add the inverter to the monitoring platform, and set the alarm reminder, the alarm information can be sent to the customer by emails. |
| Ground IFailure | 1. The ground current is too high.2. Unplug the inputs from the PV generator and check the peripheral AC system.3. When the problem is cleared, reconnect the PV panel and check the Inverter status.4. Contact local service office for help if the problem still persist. | |
| Vac Failure | 1. The PV Inverter will automatically restart within 5 minutes if the grid returns to normal.2. Make sure grid voltage conforms with the specification.3. Make sure neutral (N) wire and PE wire are connected well.4. Contact local service office for help if the problem still persist. | |
| Fac Failure | 1. Grid is not connected.2. Check grid connection cables.3. Check availability of grid. | |
| Utility Loss | 1. Not connect to the grid.2. Check if the power grid is connected to cable.3. Check the availability of power grid. | |
| PV OverVoltage | 1. Check if the PV open circuit voltage is higher or too close to the maximum input voltage or not.2. If the problem still persist when PV voltage is less than the maximum input voltage, contact local service office for help. | |
| OverTemperature | 1. The internal temperature is higher than normal value specified.2. Reduce ambient temperature.3. Move the inverter to a cool place.4. If the problem still exists, contact local service office for help. | |
| InverterFailure | Relay-CheckFailure | 1. Turn off DC switch of the inverter.2. Wait till the inverter's LCD light is off.3. Turn on DC switch and make sure it is connected.4. If the problem still exists, contact local service office for help. |
| DCI InjectionHigh | ||
| EEPROM R/WFailure | ||
| SCI Failure | ||
| SPI Failure | ||
| DC BUS High | ||
| BUSUnbalance | ||
| GFCI Failure | ||
| Ifan Fault | ||
| Efan Fault | ||
| Afan Fault | ||
| AFCI Fail | ||
| No display | 1. Turn off DC switch, take off DC connector, measure the voltage of PV array.2. Plug in DC connector, and turn on DC switch.3. If PV array voltage is lower than 250V, please check configuration of inverter module.4. If voltage is higher than 250V, please contact local office. | |
| Others | Wi-Fi module fail to connect to network | 1. If the Wi-Fi module fail to connect to network after choosing the right router hotspot and entering the right passwords, it's possible that there are special characters not supported by module in the hotspot passwords. Please modify the password to consist of only Arabic numerals or uppercase / lowercase letters.2. If the problem still exists, contact local service office for help. |
NOTICE
When sunlight is insufficient, the PV inverter may continuously start up and shut down automatically due to insufficient power generation from the PV panels, which would not lead to inverter damage.
9.5 Routine Maintenance
WARNING
• Make sure that the inverter is powered off.
- Wear proper PPE before any operations.
| Maintaining Item Mainaining Method Maintaining Period | ||
| System Clean | Check the heat sink, air intake, and air outlet for foreign matter or dust. | Once 6-12 months |
| DC Switch | Turn the DC switch on and off ten consecutive times to make sure that it is working properly. | Once a year |
| Electrical Connection | Check whether the cables are securely connected. Check whether the cables are broken or whether there is any exposed copper core. | Once 6-12 months |
| Sealing | Check whether all the terminals and ports are properly sealed. Reseal the cable hole if it is not sealed or too big. | Once a year |
10 Technical Parameters
| Technical Data GW700-XS GW1000-XS GW1500-XS GW2000-XS | ||||
| Input | ||||
| Max. Input Power (W)*1 | 910 1,300 | 1,950 2,600 | ||
| Max. Input Voltage (V) 500 500 500 | 500 | |||
| MPPT Operating Voltage Range (V) | 40~450 40~450 | 50~450 | 50~450 | |
| MPPT Voltage Range at Nominal Power (V) | 80~450 85~ | 450 125 | ~450 165 | ~450 |
| Start-up Voltage (V) | 40 | 40 | 50 | 50 |
| Nominal Input Voltage (V) | 360 | 360 | 360 | 360 |
| Max. Input Current per MPPT (A) | 12.5 12.5 | 12.5 12.5 | ||
| Max. Short Circuit Current per MPPT (A) | 15.6 15.6 | 15.6 15.6 | ||
| Max. Backfeed Current to The Array (A) | 0 | 0 | 0 | 0 |
| Number of MPP Trackers | 1 | 1 | 1 | 1 |
| Number of Strings per MPPT | 1 | 1 | 1 | 1 |
| Output | ||||
| Nominal Output Power (W) | 700 1,000 | 1,500 2,000 | ||
| Nominal Output Apparent Power (VA) | 700 1,000 | 1,500 2,000 | ||
| Max. AC Active Power (W)*2 | 800 | 1,100 1,650 | 2,200 | |
| Max. AC Apparent Power (VA)*2 | 800 1,100 | 1,650 2,200 | ||
| Nominal Power at 40°C (W)(Only for Brazil) | 700 1,000 | 1,500 2,000 | ||
| Max Power at 40°C (Including AC Overload) (W)(Only for Brazil) | 800 1,100 | 1,650 2,200 | ||
| Nominal Output Voltage (V) | 230 | 230 | 230 | 230 |
| Nominal AC Grid Frequency (Hz) | 50/60 | 50/60 | 50/60 | 50/60 |
| Max. Output Current (A) | 3.5 | 4.8 | 7.2 | 9.6 |
| Max. Output Fault Current (Peak and Duration) (A/ms) | 25@5ms | 25@5ms | 25@5ms | 25@5ms |
| Inrush Current (Peak and Duration) (A/us) | 50@2us | 50@2us | 50@2us | 50@2us |
| Nominal Output Current (A) | 3.0 | 4.3 | 6.5 | 8.7 |
| Power Factor | ~1 (Adjustable from 0.8 leading to 0.8 lagging) | |||
| Max. Total Harmonic Distortion | <3% | |||
| Maximum Output Overcurrent Protection (A) | 24 | 24 | 24 | 24 |
| Efficiency | ||||
| Max. Efficiency 97.2% 97.2% 97.3% 97.5% | |||
| European Efficiency 96.0% 96.4% 96.6% 97.0% | |||
| Protection | |||
| PV Insulation Resistance Detection Integrated | |||
| Residual Current Monitoring Integrated | |||
| PV Reverse Polarity Protection Integrated | |||
| Anti-islanding Protection Integrated | |||
| AC Overcurrent Protection Integrated | |||
| AC Short Circuit Protection Integrated | |||
| AC Overvoltage Protection Integrated | |||
| DC Switch Integrated | |||
| DC Surge Protection Type III | |||
| AC Surge Protection Type III | |||
| General Data | |||
| Operating Temperature Range (°C) | -25~+60 | ||
| Relative Humidity | 0~100% | ||
| Max. Operating Altitude (m)*3 | 4000 | ||
| Cooling Method | Natural Convection | ||
| User Interface LED, LCD (Optional), | WLAN+APP | ||
| Communication | WiFi, LAN or RS485(Optional) | ||
| Communication Protocols | Modbus-RTU (SunSpec Compliant) | ||
| Weight (kg) | 5.8 | ||
| Dimension (W×H×D mm) | 295×230×113 | ||
| Noise Emission (dB) | <25 | ||
| Topology | Non-isolated | ||
| Self-consumption at Night (W) | <1 | ||
| Ingress Protection Rating | IP65 | ||
| DC Connector | MC4 (2.5-4mm2) | ||
| AC Connector | Plug and Play Connector | ||
| Environmental Category | 4K4H | ||
| Pollution Degree | III | ||
| Overvoltage Category | DC II / AC III | ||
| Protective Class | I | ||
| The Decisive Voltage Class (DVC) | PV: C AC: C Com: A | ||
| Active Anti-islanding Method | AFDPF + AQDPF *4 | ||
| Country of Manufacture (Only for Australia) | China | ||
| Technical Data GW2500-XS GW3000-XS | ||
| Input | ||
| Max. Input Power (W)*1 | 3,250 3,900 | |
| Max. Input Voltage (V) 500 500 | ||
| MPPT Operating Voltage Range (V) 50-450 50-450 | ||
| MPPT Voltage Range at Nominal Power (V) 240-450 280-450 | ||
| Start-up Voltage (V) 50 50 | ||
| Nominal Input Voltage (V) 360 360 | ||
| Max. Input Current per MPPT (A) 12.5 12.5 | ||
| Max. Short Circuit Current per MPPT (A) 15.6 15.6 | ||
| Max. Backfeed Current to The Array (A) 0 | 0 | |
| Number of MPP Trackers | 1 | 1 |
| Number of Strings per MPPT | 1 | 1 |
| Output | ||
| Nominal Output Power (W) | 2,500 3,000 | |
| Nominal Output Apparent Power (VA) | 2,500 3,000 | |
| Max. AC Active Power (W)*2 | 2,750 | 3,300 |
| Max. AC Apparent Power (VA)*2 | 2,750 3,300 | |
| Nominal Power at 40°C (W)(Only for Brazil) | 2,500 3,000 | |
| Max Power at 40°C (Including AC Overload) (W)(Only for Brazil) | 2,750 3,300 | |
| Nominal Output Voltage (V) | 230 230 | |
| Nominal AC Grid Frequency (Hz) | 50/60 | 50/60 |
| Max. Output Current (A) | 12.0 14.3 | |
| Max. Output Fault Current (Peak and Duration) (A/ms) | 30@5ms | 30@5ms |
| Inrush Current (Peak and Duration) (A/us) | 50@2us | 50@2us |
| Nominal Output Current (A) | 10.9 13.0 | |
| Power Factor | ~1 (Adjustable from 0.8 leading to 0.8 lagging) | |
| Max. Total Harmonic Distortion | <3% | |
| Maximum Output Overcurrent Protection (A) | 32 32 | |
| Efficiency | ||
| Max. Efficiency | 97.6% 97.6% | |
| European Efficiency | 97.2% 97.2% | |
| Protection | ||
| PV Insulation Resistance Detection Integrated | ||
| Residual Current Monitoring | Integrated | |
| PV Reverse Polarity Protection Integrated | ||
| Anti-islanding Protection Integrated | ||
| AC Overcurrent Protection Integrated | ||
| AC Short Circuit Protection Integrated | ||
| AC Overvoltage Protection Integrated | ||
| DC Switch Integrated | ||
| DC Surge Protection Type III | ||
| AC Surge Protection Type III | ||
| General Data | ||
| Operating Temperature Range (°C) -25~+60 | ||
| Relative Humidity 0~100% | ||
| Max. Operating Altitude (m)*3 | 4000 | |
| Cooling Method Natural Convection | ||
| User Interface LED, LCD (Optional), WLAN+APP | ||
| Communication WiFi, LAN or RS485(Optional) | ||
| Weight (kg) 5.8 | ||
| Dimension (W×H×D mm) 295×230×113 | ||
| Noise Emission (dB) <42 | ||
| Topology Non-isolated | ||
| Self-consumption at Night (W) <1 | ||
| Ingress Protection Rating | IP65 | |
| DC Connector | MC4 (2.5-4mm2) | |
| AC Connector | Plug and Play Connector | |
| Environmental Category | 4K4H | |
| Pollution Degree | III | |
| Overvoltage Category | DC II / AC III | |
| Protective Class | I | |
| The Decisive Voltage Class (DVC) | PV: C AC: C Com: A | |
| Active Anti-islanding Method | AFDPF + AQDPF *4 | |
| Country of Manufacture (Only for Australia) | China | |
| Technical Data GW2500N-XS GW3000N-XS GW3KB-XS GW3300-XS | ||||
| Input | ||||
| Max. Input Power (W)*1 | 3,250 3,900 | 3,900 3,900 | ||
| Max. Input Voltage (V) 600 600 600 500 | ||||
| MPPT Operating Voltage Range (V) 50-550 50-550 50-550 50-450 | ||||
| MPPT Voltage Range at Nominal Power (V) | 205-450 245 | -450 240-450 | 275-450 | |
| Start-up Voltage (V) | 50 | 50 | 50 50 | |
| Nominal Input Voltage (V) | 360 | 360 | 360 | 360 |
| Max. Input Current per MPPT (A) | 13.0 | 13.0 | 13.0 | 12.5 |
| Max. Short Circuit Current per MPPT (A) | 16.3 | 16.3 16.3 | 15.6 | |
| Max. Backfeed Current to The Array (A) | 0 | 0 | 0 | 0 |
| Number of MPP Trackers | 1 | 1 | 1 | 1 |
| Number of Strings per MPPT | 1 | 1 | 1 | 1 |
| Output | ||||
| Nominal Output Power (W) | 2,500 3,000 | 3,000 3,300 | ||
| Nominal Output Apparent Power (VA) | 2,500 3,000 | 3,000 3,300 | ||
| Max. AC Active Power (W)*2 | 2,750 | 3,300 | 3,300 | 3,300 |
| Max. AC Apparent Power (VA)*2 | 2,750 3,300 | 3,300 3,300 | ||
| Nominal Power at 40°C (W)(Only for Brazil) | 2,500 3,000 | 3,000 3,300 | ||
| Max Power at 40°C (Including AC Overload) (W)(Only for Brazil) | 2,750 3,300 | 3,300 3,300 | ||
| Nominal Output Voltage (V) | 220/230 | 220/230 | 220 | 230 |
| Nominal AC Grid Frequency (Hz) | 50/60 | 50/60 | 60 | 50/60 |
| Max. Output Current (A) | 12.0 | 14.3 | 14.3 | 14.3 |
| Max. Output Fault Current (Peak and Duration) (A/ms) | 30@5ms 30@5ms | 30@5ms 30@5ms | 30@5ms | |
| Inrush Current (Peak and Duration) (A/us) | 50@2us | 50@2us | 50@2us | 50@2us |
| Nominal Output Current (A) | 11.4/10.9 | 13.6/13.0 | 13.6/13.0 | 14.3 |
| Power Factor | ~1 (Adjustable from 0.8 leading to 0.8 lagging) | |||
| Max. Total Harmonic Distortion | <3% | |||
| Maximum Output Overcurrent Protection (A) | 32 | 32 | 32 | 32 |
| Efficiency | ||||
| Max. Efficiency | 97.6% 97.6% 97.6% 97.6% | |||
| European Efficiency 97.2% 97.2% 97.2% | 97.2% | |||
| Protection | ||||
| PV Insulation Resistance Detection Integrated | ||||
| Residual Current Monitoring Integrated | ||||
| PV Reverse Polarity Protection Integrated | ||||
| Anti-islanding Protection Integrated | ||||
| AC Overcurrent Protection Integrated | ||||
| AC Short Circuit Protection Integrated | ||||
| AC Overvoltage Protection Integrated | ||||
| DC Switch Integrated | ||||
| DC Surge Protection Type III (Type II Optional) Type III | ||||
| AC Surge Protection Type III | ||||
| AFCI | Optional | |||
| General Data | ||||
| Operating Temperature Range (°C) | -25~+60 | |||
| Relative Humidity | 0~100% | |||
| Max. Operating Altitude (m)*3 | 4000 | |||
| Cooling Method | Natural Convection | |||
| User Interface LED, LCD (Optional), WLAN+APP | ||||
| Communication | WiFi, LAN or RS485(Optional) | |||
| Weight (kg) | 5.8 | |||
| Dimension (W×H×D mm) | 295×230×113 | |||
| Noise Emission (dB) | <42 | |||
| Topology | Non-isolated | |||
| Self-consumption at Night (W) | <1 | |||
| Ingress Protection Rating | IP65 | |||
| DC Connector | MC4 (2.5-4mm2) | |||
| AC Connector | Plug and Play Connector | |||
| Environmental Category | 4K4H | |||
| Pollution Degree | III | |||
| Overvoltage Category | DC II / AC III | |||
| Protective Class | I | |||
| The Decisive Voltage Class (DVC) | PV: C AC: C Com: A | |||
| Active Anti-islanding Method | AFDPF + AQDPF *4 | |||
| Country of Manufacture (Only for Australia) | China | |||
| Technical Data GW700-XS-11 GW1000-XS-11 GW1500-XS-11 GW2000-XS-11 | ||||
| Input | ||||
| Max. Input Power (W)*1 | 910 1,300 | 1,950 2,600 | ||
| Max. Input Voltage (V) 500 | 500 500 500 | |||
| MPPT Operating Voltage Range (V) | 40~450 40~ | 450 50~450 50~450 | ||
| MPPT Voltage Range at Nominal Power (V) | 65~450 85~ | 450 125~450 165~ | 450 | |
| Start-up Voltage (V) 40 40 | 50 | 50 | ||
| Nominal Input Voltage (V) | 360 360 360 360 | |||
| Max. Input Current per MPPT (A) | 15 15 | 15 | 15 | |
| Max. Short Circuit Current per MPPT (A) | 18.75 | 18.75 | 18.75 | 18.75 |
| Max. Backfeed Current to The Array (A) | 0 | 0 | 0 | 0 |
| Number of MPP Trackers | 1 | 1 | 1 | 1 |
| Number of Strings per MPPT | 1 | 1 | 1 | 1 |
| Output | ||||
| Nominal Output Power (W) | 700 1,000 | 1,500 2,000 | ||
| Nominal Output Apparent Power (VA) | 700 1,000 | 1,500 2,000 | ||
| Max. AC Active Power (W)*2 | 800 1,100 | 1,650 2,200 | ||
| Max. AC Apparent Power (VA)*2 | 800 1,100 | 1,650 2,200 | ||
| Nominal Power at 40°C (W)(Only for Brazil) | 700 1,000 | 1,500 2,000 | ||
| Max Power at 40°C (Including AC Overload) (W)(Only for Brazil) | 800 1,100 | 1,650 2,200 | ||
| Nominal Output Voltage (V) | 220/230 | 220/230 | 220/230 220/230 | |
| Output Voltage Range (V) | 154~288 | 154~288 | 154~288 154~288 | |
| Nominal AC Grid Frequency (Hz) | 50/60 50/60 | 50/60 | 50/60 | |
| AC Grid Frequency Range (Hz) | 45~55/57~63 | 45~55/57~63 | 45~55/57~63 | 45~55/57~63 |
| Max. Output Current (A) | 3.5 | 4.8 | 7.2 | 9.6 |
| Max. Output Fault Current (Peak and Duration) (A/ms) | 25@5ms 25@5ms 25@5ms | |||
| Inrush Current (Peak and Duration) (A/us) | 50@2us 50@2us 50@2us | |||
| Nominal Output Current (A) | 3.0 4.3 6.5 8.7 | |||
| Power Factor ~1 (Adjustable from 0.8 leading to 0.8 lagging) | ||||
| Max. Total Harmonic Distortion | <3% | |||
| Maximum Output Overcurrent Protection (A) | 22.3 22.3 22.3 22.3 | |||
| Efficiency | ||||
| Max. Efficiency 97.2% 97.2% 97.3% | 97.5% | |||
| European Efficiency | 96.0% 96.4% 96.6% | 97.0% | ||
| Protection | ||||
| PV Insulation Resistance Detection | Integrated | |||
| Residual Current Monitoring | Integrated | |||
| Anti-islanding Protection | Integrated | |||
| AC Overcurrent Protection | Integrated | |||
| AC Short Circuit Protection | Integrated | |||
| AC Overvoltage Protection | Integrated | |||
| DC Switch | Integrated | |||
| DC Surge Protection | Type III (Type II Optional) | |||
| AC Surge Protection | Type III | |||
| AFCI | Optional | |||
| Emergency Power Off | Optional | |||
| Remote Shutdown | Optional | |||
| General Data | ||||
| Operating Temperature Range (°C) | -25~+60 | |||
| Relative Humidity | 0~100% | |||
| Max. Operating Altitude (m)*3 | 3000 | |||
| Cooling Method | Natural Convection | |||
| User Interface | LED, LCD, WLAN+APP | |||
| Communication | WiFi or LAN or RS485(Optional) | |||
| Weight (kg) | 5.8 | |||
| Dimension (W×H×D mm) | 295×230×113 | |||
| Noise Emission (dB) | <25 | |||
| Topology | Non-isolated | |||
| Self-consumption at Night (W) | <1 | |||
| Ingress Protection Rating | IP65 | |||
| DC Connector | MC4 (2.5-4mm2) | |||
| AC Connector | plug and play connector | |||
| Environmental Category | 4K4H | |||
| Pollution Degree | III | |||
| Overvoltage Category | DC II / AC III | |||
| Protective Class | I | |||
| The Decisive Voltage Class (DVC) | PV: C AC: C Com: A | |||
| Active Anti-islanding Method | AFDPF + AQDPF *4 | |||
| Country of Manufacture (Only for Australia) | China | |||
| Technical Data GW2500-XS-11 GW3000-XS-11 GW3000-XS-B11 | |||
| Input | |||
| Max. Input Power (W)*1 | 3,250 3,900 | 3,900 | |
| Max. Input Voltage (V) 600 600 600 | |||
| MPPT Operating Voltage Range (V) 50~550 50~550 50~550 | |||
| MPPT Voltage Range at Nominal Power (V) | 200~450 240~450 240~450 | ||
| Start-up Voltage (V) 50 50 | 50 | ||
| Nominal Input Voltage (V) | 360 | 360 | 360 |
| Max. Input Current per MPPT (A) | 15 15 | 15 | |
| Max. Short Circuit Current per MPPT (A) | 18.75 | 18.75 | 18.75 |
| Max. Backfeed Current to The Array (A) | 0 | 0 | 0 |
| Number of MPP Trackers | 1 | 1 | 1 |
| Number of Strings per MPPT 1 1 1 | |||
| Output | |||
| Nominal Output Power (W) 2,500 3,000 | 3,000 | ||
| Nominal Output Apparent Power (VA) 2,500 3,000 3,000 | |||
| Max. AC Active Power (W)*2 | 2,750 3,300 | 3,300 | |
| Max. AC Apparent Power (VA)*2 | 2,750 3,300 | 3,300 | |
| Nominal Power at 40°C (W)(Only for Brazil) | 2,500 3,000 | 3,000 | |
| Max Power at 40°C (Including AC Overload) (W)(Only for Brazil) | 2,750 3,300 | 3,300 | |
| Nominal Output Voltage (V) 220/230 220/230 220 | |||
| Output Voltage Range (V) 154~288 154~288 154~288 | |||
| Nominal AC Grid Frequency (Hz) 50/60 | 50/60 | 60 | |
| AC Grid Frequency Range (Hz) | 45~55/57~63 | 45~55/57~63 | 57~63 |
| Max. Output Current (A) | 12 | 14.3 | 14.3 |
| Max. Output Fault Current (Peak and Duration) (A) | 25A@5ms | 30A@5ms | 30A@5ms |
| Inrush Current (Peak and Duration) (A) | 50A@2us | 50A@2us 50A@2us | |
| Nominal Output Current (A) | 11.4/10.9 | 13.6/13.0 | 13.6 |
| Power Factor | ~1 (Adjustable from 0.8 leading to 0.8 lagging) | ||
| Max. Total Harmonic Distortion | <3% | ||
| Maximum Output Overcurrent Protection (A) | 31.5 | 31.5 | 31.5 |
| Efficiency | |||
| Max. Efficiency | 97.6% 97.6% | 97.6% | |
| European Efficiency | 97.2% 97.2% | 97.2% | |
| Protection | |||
| PV Insulation Resistance Detection | Integrated | ||
| Residual Current Monitoring | Integrated | ||
| Anti-islanding Protection | Integrated | ||
| AC Overcurrent Protection | Integrated | ||
| AC Short Circuit Protection | Integrated | ||
| AC Overvoltage Protection | Integrated | ||
| DC Switch | Integrated | ||
| DC Surge Protection | Type III (Type II Optional) | Type III | |
| AC Surge Protection | Type III | ||
| AFCI | Optional | ||
| Emergency Power Off | Optional | ||
| Remote Shutdown Optional | |||
| General Data | |||
| Operating Temperature Range (°C) -25~+60 | |||
| Relative Humidity 0~100% | |||
| Max. Operating Altitude (m)*3 | 3000 | ||
| Cooling Method Natural Convection | |||
| User Interface LED, LCD, WLAN+APP | |||
| Communication WiFi or LAN or RS485(Optional) | |||
| Weight (kg) 5.8 | |||
| Dimension (W×H×D mm) 295×230×113 | |||
| Noise Emission (dB) <30 | |||
| Topology Non-isolated | |||
| Self-consumption at Night (W) <1 | |||
| Ingress Protection Rating IP65 | |||
| DC Connector MC4 (2.5-4mm2) | |||
| AC Connector plug and play connector | |||
| Environmental Category 4K4H | |||
| Pollution Degree III | |||
| Overvoltage Category | DC II / AC III | ||
| Protective Class | I | ||
| The Decisive Voltage Class (DVC) | PV: C AC: C Com: A | ||
| Active Anti-islanding Method | AFDPF + AQDPF *4 | ||
| Country of Manufacture (Only for Australia) | China | ||
*1: For Australia Max. Input Power (W), GW700-XS-11 is 945, GW1000-XS-11 is 1350, GW1500-XS-11 is 2025, GW2000-XS-11 is 2700, GW2500-XS-11 is 3375, GW3000-XS-11 is 4050.
*2: For Chile Max. AC Active Power (W) & Max.Output Apparent Power(VA): GW700-XS-11 is 700, GW1000-XS-11 is 1000, GW1500-XS-11 is 1500, GW2000-XS-11 is 2000, GW2500-XS-11 is 2500, GW3000-XS-11 is 3000
*3: For Australia Max. Operating Altitude (m) is 3000
*4: AFDPF: Active Frequency Drift with Positive Feedback, AQDPF: Active Q Drift with Positive Feedback

Official Website
GoodWe Technologies Co., Ltd.

No. 90 Zijin Rd., New District, Suzhou, 215011, China

www.goodwe.com

service@goodwe.com

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