• Pure sine wave inverter/solar power inverter 5KVA 96/110/120V with isolate tranformer System 1
Pure sine wave inverter/solar power inverter 5KVA 96/110/120V with isolate tranformer

Pure sine wave inverter/solar power inverter 5KVA 96/110/120V with isolate tranformer

Ref Price:
get latest price
Loading Port:
Qingdao
Payment Terms:
TT OR LC
Min Order Qty:
1 unit
Supply Capability:
800 unit/month

Add to My Favorites

Follow us:


OKorder Service Pledge

Quality Product, Order Online Tracking, Timely Delivery

OKorder Financial Service

Credit Rating, Credit Services, Credit Purchasing

Specifications

1.using IGBT from Mitsubishi company 
2.using American ATEMEL company microprocessor 
3.Max. Efficiency>94% 


Features:

1. using IGBT from Mitsubishi company as the power components
2. using American ATEMEL company microprocessor as figure controller
3. perfect protection and warning functions
4. circuit frame compact,Max. Efficiency≥94%
5. with wide input voltage range
6. RS232/485 communication,multi communication interface can be selected
7. big-screen English LCD, perfect display, interface-friendly



  Off Grid Pure Sine Wave Inverter 5KW 96/110/120V for wind power and PV power with factory price

 

 


Technical Data Sheet

Type

ND96-5KD

ND110-5KD

DC input

Input rated voltage

96 VDC

110 VDC

Input rated current

52 A

45.5 A

Input DC voltage range

75-135 VDC

80-145 VDC

 

 

AC input

Allow input voltage   range

110 VAC / 120 VAC   / 220 VAC / 240 VAC ± 15%

Input rated current

45.5A / 41.7A / 22.5 A / 21A

Bypass transfer time

4 ms

 

 

 

 

AC output

Rated capacity

5KVA

Output rated power

4KW

Output rated voltage   and frequency

110 VAC / 120 VAC   / 220 VAC / 240 VAC50Hz / 60Hz

Output rated current

45.5A / 41.7A / 22.5 A / 21A

Output voltage accuracy

110 VAC / 120 VAC   / 220 VAC / 240 VAC± 2%

Output frequency   accuracy

50Hz / 60Hz ± 0.05%

Waveform distortion   (THD).
  (Linear load)

≤3%

Dynamic response time
  (Load 0←→100%)

5%

Power factor (PF)

0.8

Overload capacity

120%,3minutes,150%,10second

Crest factor (CF)

3:1

Inverter efficiency

90%

Working Environment

Dielectric strength

1500VAC,1minute

Noise (1m)

≤50dB

Ambient temperature

-10~+50

Humidity

0~90%,No condensation

Altitude

≤5000 m

Industrial Frequency   Transformer

Yes

Production function

Input reverse protection,   input under-voltage protection, output overload protection, output short   circuit protection, thermal protection

Dimensions

482*420*223mm

Weight

52kg

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 


 


Q:Are there any risks of electrical short circuits with solar energy systems?
Solar energy systems, like any other electrical system, have the potential for electrical short circuits. When there is an unintended path of low resistance, a short circuit occurs and allows a large amount of current to flow. This can be caused by faulty wiring, damaged components, or improper installation. Short circuits can lead to overheating, electrical fires, or system damage. The excessive current flow can melt wires, burn insulation, and even harm the solar panels themselves. In extreme cases, short circuits can cause explosions or other dangerous situations. To reduce the risks of short circuits, it is crucial to have qualified professionals install the system according to safety guidelines and local codes. Regular maintenance and inspections are also important for identifying and addressing potential issues. Installing a circuit breaker or fuse within the system can automatically disconnect the circuit in case of a short circuit. Using high-quality components and wiring specifically designed for solar energy systems can also help minimize the risks of short circuits. It is important to follow the manufacturer's instructions and guidelines for system maintenance and operation. In conclusion, although there are risks of electrical short circuits with solar energy systems, these risks can be effectively managed and minimized through proper installation, regular maintenance, and adherence to safety guidelines.
Q:Can solar energy systems be used in powering theme parks or water parks?
Yes, solar energy systems can certainly be used to power theme parks or water parks. These types of parks consume a significant amount of energy due to lighting, water pumps, rides, and various other facilities. Solar panels can be installed on rooftops, parking lots, or dedicated areas to harness sunlight and convert it into electricity. This renewable energy source can help reduce operating costs, decrease carbon emissions, and promote sustainability in the entertainment industry.
Q:How do solar energy systems impact the electric utility industry?
Solar energy systems have a significant impact on the electric utility industry by increasing the supply of renewable energy and reducing the reliance on traditional fossil fuels. This shift towards solar power has prompted utilities to adapt their infrastructure and business models to accommodate distributed generation, such as rooftop solar panels. Additionally, the integration of solar energy into the grid has led to increased grid stability and lowered electricity costs for consumers. However, it has also presented challenges for utilities in terms of managing intermittent power generation and ensuring grid reliability. Overall, solar energy systems are reshaping the electric utility industry towards a more sustainable and decentralized future.
Q:How do solar energy systems impact the energy poverty gap?
Solar energy systems have the potential to significantly reduce the energy poverty gap by providing affordable and sustainable electricity to those who lack access to traditional energy sources. These systems empower communities to generate their own clean energy, enabling them to break free from reliance on expensive and polluting fuels. Moreover, solar energy can be harnessed in remote and off-grid areas, reaching populations that are often neglected by traditional energy infrastructure. By bridging the energy poverty gap, solar energy systems contribute to socio-economic development, improve living conditions, and enhance opportunities for education, healthcare, and economic growth in underserved communities.
Q:Can solar energy systems be used for powering off-grid wildlife monitoring stations?
Yes, solar energy systems can be used for powering off-grid wildlife monitoring stations. Solar panels can capture sunlight and convert it into electricity, which can then be stored in batteries for use during the night or cloudy days. This makes it a reliable and sustainable source of power for remote wildlife monitoring stations that are located far away from the grid. Additionally, solar energy systems are cost-effective and environmentally friendly, making them an ideal choice for powering off-grid wildlife monitoring stations.
Q:How do solar energy systems affect wildlife and ecosystems?
Solar energy systems have a minimal impact on wildlife and ecosystems compared to conventional energy sources. While there may be some localized disturbance during the construction phase, once operational, solar energy systems do not emit greenhouse gases or release pollutants that harm ecosystems. Additionally, appropriate site selection, design, and management can mitigate potential impacts on wildlife, such as bird collisions or habitat fragmentation. Overall, solar energy systems offer a cleaner and more sustainable alternative, promoting a healthier environment for wildlife and ecosystems.
Q:What is the difference between a monofacial and bifacial solar panel?
A monofacial solar panel is a conventional type of solar panel that only uses one side of the panel to capture sunlight and convert it into electricity. Photovoltaic (PV) cells on the single side of the panel absorb sunlight and produce electrical current. Monofacial panels are the most commonly used type of solar panels. On the other hand, a bifacial solar panel is designed to capture sunlight from both sides of the panel. It has PV cells on both the front and back sides, allowing it to generate electricity from sunlight that is reflected or scattered onto the back side. This design has an advantage over monofacial panels as it can generate more energy by harnessing light that would otherwise be wasted. The main difference between monofacial and bifacial solar panels lies in their efficiency and energy output. Bifacial panels can produce more electricity per unit area than monofacial panels because they can capture light from both sides. This makes bifacial panels a suitable choice for situations where space is limited and maximizing energy production is crucial. Additionally, bifacial panels can benefit from certain installation configurations that allow light to bounce off the ground or other nearby surfaces onto the backside of the panel, further increasing their energy output. This makes them particularly effective in environments with high levels of ground reflectance, such as snow-covered areas or locations with white rooftops. However, it is important to note that the increased efficiency and energy output of bifacial panels come at a higher cost compared to monofacial panels. Bifacial panels require more complex design and manufacturing processes, which contribute to their higher price. Additionally, the installation of bifacial panels may require specialized mounting systems to ensure proper exposure to both sides of the panel. To summarize, the main difference between monofacial and bifacial solar panels is their ability to capture sunlight. Monofacial panels use only one side of the panel to generate electricity, while bifacial panels utilize both sides, resulting in higher efficiency and energy output. However, the higher cost and specific installation requirements make bifacial panels a more specialized choice compared to the widely used monofacial panels.
Q:What is the difference between solar thermal and solar PV systems?
Solar thermal systems use sunlight to heat water or other fluids, which can then be used for various purposes like heating buildings or generating electricity. On the other hand, solar PV (photovoltaic) systems directly convert sunlight into electricity using solar panels made up of photovoltaic cells. While solar thermal systems are primarily used for heating, solar PV systems are designed for generating electricity.
Q:Can solar energy systems be used for powering drones?
Yes, solar energy systems can be used for powering drones. Solar panels can be installed on the surface of drones to capture sunlight and convert it into electrical energy, which can then be used to power the drone's motors and other electronic components. This allows drones to have extended flight times and reduces the dependence on traditional battery power.
Q:Can solar energy systems be used for powering telecommunications networks?
Yes, solar energy systems can indeed be used for powering telecommunications networks. Solar power is a sustainable and renewable energy source that can be harnessed to generate electricity for various applications, including powering telecommunication infrastructure. Solar energy systems consist of solar panels that convert sunlight into electricity through the photovoltaic (PV) effect. These PV panels are typically installed on rooftops, ground-mounted arrays, or even integrated into the structure of telecommunication towers. They absorb sunlight during the day and convert it into direct current (DC) electricity. To utilize this electricity for powering telecommunications networks, an inverter is used to convert the DC electricity into alternating current (AC), which is the standard form of electricity used in most electronic devices. The AC electricity generated by solar panels can then be used to power telecommunication equipment such as base stations, antennas, transmitters, and receivers. The benefits of using solar energy systems for powering telecommunications networks are numerous. Firstly, solar energy is abundant and available in almost all geographical locations, making it a viable option for powering remote or off-grid telecommunication sites. This reduces the reliance on traditional grid electricity, which may not be available or reliable in certain areas. Secondly, solar power is environmentally friendly, emitting zero greenhouse gases during operation. By using solar energy, telecommunication networks can significantly reduce their carbon footprint and contribute to the global transition towards clean energy sources. Moreover, solar energy systems are low maintenance and have a long lifespan, providing a reliable and cost-effective solution for powering telecommunication infrastructure. Once installed, solar panels require minimal maintenance and can last for 25-30 years or even longer with proper care. In conclusion, solar energy systems can be effectively used for powering telecommunications networks. They offer a sustainable and reliable source of electricity, reduce environmental impact, and provide a cost-effective solution for remote or off-grid telecommunication sites. With the increasing focus on renewable energy, solar power is becoming an increasingly popular choice for powering various sectors, including telecommunications.

1. Manufacturer Overview

Location
Year Established
Annual Output Value
Main Markets
Company Certifications

2. Manufacturer Certificates

a) Certification Name  
Range  
Reference  
Validity Period  

3. Manufacturer Capability

a)Trade Capacity  
Nearest Port
Export Percentage
No.of Employees in Trade Department
Language Spoken:
b)Factory Information  
Factory Size:
No. of Production Lines
Contract Manufacturing
Product Price Range

Send your message to us

This is not what you are looking for? Post Buying Request

Similar products

New products

Hot products


Related keywords