Solar System New Product Introduction

Sunchees new Solar system provides stable power supply for your residential farm commercial factory and other places

Sunchees is a solar energy dealer with more than ten years of experience. It has its own factory. The solar energy engineers with many years of experience control the quality of the products and have won 90% of the customers' praise. sunchees' products have also been tested by the market and successfully sold all over the world. We are also growing continuously and more and more friends know us

Our company's products mainly include off-grid solar energy systems, grid-connected solar energy systems, three-phase solar energy systems and hybrid solar energy systems. You can consult us according to your needs and we can also provide you with suggestions. The batteries include lithium batteries and gel batteries. We are fully confident in the machines produced by our own factory.

The solar energy system I want to introduce today is the 20kw and 25kw solar split-phase system. This system can meet the two voltage outputs of the mains, which greatly facilitates the use of life loads. After factory testing, the use condition is very stable. The inverter is equipped with a touch screen, which is easy to use. It has four wheels for easy installation and movement. The use of the system can be monitored through WiFi, which allows us to no longer be limited to understanding the situation only at the installation site. It is a good technical improvement.

If you want to know more about sunrisees, please contact us and we will answer you for free.

Which battery is best for solar energy storage?

In various countries, renewable energy is becoming more and more mainstream development. As photovoltaic power stations are also popularized, solar energy storage systems, which can provide a stable power supply and achieve self-sufficient electricity for homes, businesses and other places, have attracted public attention. The choice of solar energy storage batteries is the main factor in the operating cost, efficiency, service life and safety of photovoltaic energy storage systems.

Which battery is the best choice for solar photovoltaic energy storage system? What are the advantages and disadvantages of different batteries? Sunchees will analyze various types of batteries for you, and you will definitely make your own choice after reading it.

1、Lithium-ion battery

Lithium batteries are the mainstream choice for solar energy storage systems. Lithium batteries are high-energy-density batteries that are suitable for home and commercial systems. The number of cycles can reach more than 6,000 times. They are highly efficient, with a charging and discharging efficiency of more than 92%. They can effectively reduce energy loss and do not require regular maintenance. They are usually equipped with a battery management system (BMS). Long-term use of solar energy storage lithium batteries is a cost-effective option, with a high initial cost. Lithium batteries can be used for home energy storage, industrial and commercial energy storage, off-grid systems, and grid-connected systems. Lithium iron phosphate batteries (LFP) are preferred for safety and efficiency, as well as ternary lithium (NMC).

2、Lead-acid batteries

Lead-acid batteries are an older solar system configuration battery solution. They are relatively cheap and easy to recycle, but they have a very short lifespan, with only 300-500 cycles. The charging and discharging efficiency is about 75%, which is relatively inefficient and needs to be replaced frequently. They are suitable for off-grid systems or backup power sources with a very low budget.

3、Flow Battery

Liquid flow batteries have independent designs for power and capacity, are suitable for megawatt projects, have a cycle count of more than 15,000 times, have an ultra-long life, are suitable for daily charging and discharging, have no risk of combustion, are highly safe, and have a relatively high price. Liquid flow batteries can be considered for grid-level solar energy storage and high-power energy storage systems

4、Sodium-sulfur battery

Sodium-sulfur batteries are high-temperature batteries suitable for large-scale applications. They need to be operated at 300°C and are relatively complex to maintain.

5、Solid-state batteries

Solid-state batteries have higher energy density and safety, but their current cost is extremely high and the technology is not yet mature. They are potential batteries in the future energy storage market.

Recommended choice

In general, lithium batteries are the best choice for home and small- and medium-sized solar energy storage systems based on cycle life, cost, and adaptability. If the budget is limited and regular maintenance is possible, lead-acid batteries are also an option. For large projects or grid energy storage projects, flow batteries or lithium batteries are more recommended.

What are the steps to take before installing a solar system?

Before installing a solar energy system, what preparations and understandings do you need to make to ensure that the system provides you with a stable power supply reasonably and safely? We will explain the key points that need to be taken to ensure that you can use your solar energy system happily and satisfactorily.

1. Estimate the kilowatts of your solar energy system

2. Determine the installation site

3. Understand the local sunshine time

4. Choose a solar energy system

5. Understand local policies on installing solar energy systems

6. Choose suppliers and installers

1. Estimate the kilowatts of your solar energy system

According to the monthly electricity bill, calculate the average electricity consumption of your home or company and determine the power of the solar energy system Know the load output voltage of your country and choose the type of solar energy system, single-phase solar energy system, split-phase solar energy system, three-phase solar energy system

2. Determine the installation site

Solar panels can be installed on the roof or on the ground. If installed on the roof, you need to consider the weighing capacity. If installed on the ground, you need to consider whether the ground foundation is solid The installation direction is selected based on the maximum sun exposure surface

3. Understand the local sunshine time

Check the sunshine data and climate to see if it is suitable to install a solar energy system

4. Choose a solar energy system

Generally, solar energy systems are divided into off-grid solar energy systems, grid-connected solar energy systems and off-grid solar energy systems. If you need energy storage equipment, you have to choose off-grid solar energy systems with batteries and off-grid solar energy systems

5. Understand local policies on installing solar energy systems

Solar energy As a renewable clean energy, many countries have subsidies for installing solar energy systems and strongly encourage everyone to install solar energy systems. You can pay attention to the subsidy application process to save the cost of installing solar energy systems

6. Choose suppliers and installers

Verify the qualifications of solar energy suppliers. Customers with rich experience and many good reviews are definitely the best choice. The relevant services of solar energy suppliers are also very important. Whether it can be customized, whether the transportation is fast, whether the product quality is good, whether the follow-up service can keep up, and how long the warranty period is, all need to be verified and compared. Installers must also choose experienced and responsible engineering teams.

SUNCHEES hope everyone can successfully install the solar energy system and save the electricity bills of their own families or companies. The solar energy system will bring you more surprises. If you have any questions, please contact us. Sunchees is a one-stop solar energy product industry and trade merchant. It has many years of precipitation in this industry, mature and stable technology, and professional engineers are connected throughout the process. There is no need to worry about encountering difficult problems. Follow us to learn more about solar energy dry goods sharing

Batteries in Photovoltaic Systems - Applications and Maintenance

In independent photovoltaic systems, batteries play a very important and critical role as a medium for storing electrical energy. This is because without sunlight, solar photovoltaic systems cannot store electrical energy and deliver it to the load.

When there is no sunlight, we need to store energy in an independent system to run our electrical appliances, and in grid-connected systems, if the power grid is operating normally, then even when there is less or no sunlight, the power grid can provide the required energy.

With technological advancements and market growth, the cost of solar photovoltaic modules is decreasing, while the cost of batteries is becoming a significant component of independent systems. Improper use of batteries can shorten the lifespan of such critical equipment in the system.

A battery is a two-terminal device, with one being the positive terminal and the other the negative terminal. When a battery is charging, a voltage difference is generated across these two terminals. It is precisely because of this voltage difference across the two terminals that current flows when the battery is connected to electrical or electronic devices.

There are various types of batteries available in the market, which differ in shape, size, rated voltage, storage capacity, charge-discharge cycles, battery life, and technology. Batteries are divided into rechargeable and non-rechargeable batteries.

Rechargeable Batteries

Just as adding water to a water tank, independent solar photovoltaic systems also require batteries to restore their charge. The charge level of the battery will decrease as it meets the load demand, just as the water level in a water tank decreases when it is in use.

Once the charge level (like the water level dropping) decreases, it is necessary to continuously replenish the charge to prevent system interruption. This process of restoring charge or recharging the battery is called "charging."

During the charging process, electrical energy is delivered to the battery and is converted into chemical energy there. The process of consuming the battery's electrical energy is called "discharging." During the discharging process, the chemical energy in the battery is converted into electrical energy and delivered to the load.

Therefore, a battery has a charging and discharging process. One complete charging and discharging process of a battery is called a battery charge cycle. Some batteries have multiple charge-discharge cycles, while others do not. Batteries with multiple cycles are called "rechargeable batteries."

These rechargeable batteries with multiple cycles are widely used in solar photovoltaic applications because they ensure continuous power supply to the load even when there is insufficient or no sunlight. Without sunlight, the implementation of independent solar photovoltaic systems would be very unreliable and difficult.

State of Charge (SOC) and Depth of Discharge (DOD)

In reality, not all the electrical energy stored in a battery can be used for load applications. Only a certain proportion of the stored electrical energy can be used to run the load, which is known as the Depth of Discharge (DOD) limit, measured as a percentage.

If the DOD limit of a battery is 30%, then only 30% of the stored electrical energy can be used to run the load. If the DOD limit is 60%, then only 60% of the electrical energy can be used; if the DOD limit is 70%, then only 70% of the electrical energy can be used; if the DOD limit is 80%, then only 80% of the electrical energy can be used to run the load.

Ideally, the DOD limit of a battery should be 100%, and in practical applications, it should be as high as possible. For solar photovoltaic applications, a higher DOD limit percentage is preferred. The DOD limit percentage varies for different batteries; lithium-ion batteries have a DOD limit percentage of about 85% to 90%, while lead-acid batteries, which are most commonly used in solar photovoltaic applications, have a DOD limit percentage of about 50%.

In addition to the DOD limit, DOD can be simply defined as the ratio of the amount of charge used in the battery to the total charge capacity of the battery. The terminal voltage of the battery decreases as the stored charge is used, i.e., DOD increases. The terminal voltage of a fully charged battery is higher than that of a fully or partially discharged battery.

Manufacturers specify the maximum allowable DOD limit for their batteries and recommend not discharging the battery below the specified DOD limit, as this can rapidly shorten the battery's lifespan.

State of Charge (SOC): To determine charging time, it is crucial to understand the current charge level of the battery. The current charge level is represented by the State of Charge (SOC), expressed as a percentage.

For example, an SOC of 70% indicates that the battery stores 70% of its total electrical energy. DOD can also be used to represent SOC, with DOD being the inverse of SOC. If we subtract 70% from 100%, we get 30%, which represents the battery's DOD. It can be mathematically represented by either of the following formulas:

DOD (%) = 100% – SOC (%)

DOD (%) + SOC (%) = 100%

Let's understand this with a simple example: if the DOD is 80%, then by using either of the above formulas, we can determine the percentage of SOC as:

DOD (%) + SOC (%) = 100%

80% + SOC (%) = 100%

SOC (%) = 20%

As we continue to use the battery, the SOC level decreases, while the DOD level increases. It is important to note that the discharge amount of the battery should not fall below the DOD level specified by the manufacturer to avoid shortening the battery's lifespan.

The SOC of a battery can be measured by measuring the terminal voltage of the battery. We know that the SOC of a battery decreases during use, and therefore the terminal voltage of the battery also decreases as the SOC decreases.

Therefore, the higher the SOC, the higher the terminal voltage; the lower the SOC, the lower the terminal voltage. The relationship between the open-circuit voltage of lead-acid batteries and SOC (%) is shown in Figure 3 below.

How Long Do Solar Panels Take to Pay for Themselves?

Investing in solar panels is a smart financial decision for many homeowners, but one of the most common questions is: How long until solar panels pay for themselves? The answer depends on several factors, including installation costs, energy savings, incentives, and local electricity rates. Understanding the solar panel return on investment (ROI) can help you determine whether going solar is worth it for your home.

Key Factors Affecting Solar Payback Period

1. Upfront Costs vs. Long-Term Savings

The initial cost of solar panels includes equipment, installation, and permits. However, federal tax credits, state incentives, and rebates can significantly reduce this expense. The solar power payback calculator** helps estimate how long it will take to recoup your investment based on these factors. 

2. Energy Savings & Electricity Rates

Solar panels generate free electricity, reducing or even eliminating your monthly utility bills. If electricity prices rise, your savings increase, shortening the payback period.

3. Solar Incentives & Tax Credits

The Federal Solar Investment Tax Credit (ITC)** allows homeowners to deduct 30% of their solar installation costs from their federal taxes (as of 2024). Some states offer additional rebates, further improving ROI.

4. System Efficiency & Sunlight Availability

Homes in sunnier regions (like Arizona or California) typically see faster payback periods than those in cloudier areas. High-efficiency panels also generate more power, accelerating savings.

Calculating Your Solar Payback Period To estimate how long it will take for your solar panels to pay for themselves:

1. Total System Cost – Subtract incentives (e.g., $25,000 system – $7,500 ITC = $17,500 net cost).

2. Annual Savings– If your solar panels save $1,500 per year on electricity, divide the net cost by annual savings:

$17,500 ÷ $1,500 ≈ 11.7 years payback period.

Many homeowners see a payback period between 6 to 12 years, with panels lasting 25+ years, meaning over a decade of free electricity after breaking even.

Using a Solar Power Payback Calculator

Online tools like those from the National Renewable Energy Laboratory (NREL)or solar providers can give a personalized estimate by factoring in:

- Local electricity rates

- Solar irradiance in your area

- Financing options (cash purchase vs. solar loans)

Maximizing Your Solar Panel Return on Investment

- Choose high-efficiency panels for better long-term savings.

- Take advantage of net metering (selling excess power back to the grid).

- Monitor system performance to ensure optimal energy production.

Conclusion

The time it takes for solar panels to pay for themselves varies, but most systems achieve ROI within 6–12 years With rising energy costs and strong incentives, solar remains a financially sound investment. Use a solar power payback calculator to determine your exact timeline and start saving on energy bills sooner!

Would you like help estimating your solar payback period based on your location and energy usage? Let me know!

What are the advantages of lithium iron phosphate （LiFePO4）batteries?

Lithium iron phosphate (LiFePO4) batteries have become a leading technology in energy storage, finding a place in applications ranging from electric vehicles (EVs) to renewable energy systems. As a subtype of lithium-ion batteries, LiFePO4 has unique chemical and structural properties that address many of the limitations of traditional lithium-ion batteries. Below, we explore the key advantages that are driving its widespread adoption.

1. Superior safety and thermal stability

2. Extended Cycle Life

3. Long-term cost-effectiveness

4. Environmental and material advantages

5: High performance in extreme conditions

6: Versatile applications

7. Stable voltage output

1. Superior safety and thermal stability

Safety is a primary concern in battery technology. LiFePO4 batteries excel in this regard due to their stable chemistry. Unlike lithium cobalt oxide (LiCoO2) or nickel-based lithium batteries, LiFePO4's olivine crystal structure resists thermal runaway - a chain reaction that causes overheating or combustion. Even in the event of high temperatures, physical damage, or overcharging, LiFePO4 batteries are less prone to catastrophic failure, making them ideal for high-risk environments such as EVs and residential energy storage.

2. Extended Cycle Life

LiFePO4 batteries have an exceptionally long service life, typically exceeding 2,000-5,000 charge-discharge cycles while retaining 80% of their original capacity. In contrast, conventional lithium-ion batteries typically degrade after 500-1,000 cycles. This long life reduces replacement frequency and total cost of ownership, especially in applications that require daily cycling, such as solar energy storage or industrial equipment.

3. Long-term cost-effectiveness

While LiFePO4 batteries may cost more upfront than lead-acid or standard lithium-ion batteries, their extended service life and lower maintenance requirements make them more economical in the long run. They avoid the frequent replacement and performance degradation issues found in lead-acid batteries, providing significant cost savings for commercial and residential users.

4. Environmental and material advantages

LiFePO4 batteries do not contain toxic heavy metals such as cobalt and nickel, which are associated with ethical mining issues and environmental hazards. Its main components, iron and phosphate, are abundant, non-toxic, and easily recyclable. This is in line with global sustainable development goals and reduces reliance on scarce or geopolitically sensitive materials.

5: High performance in extreme conditions

These batteries operate efficiently over a wide temperature range (-20°C to 60°C) and maintain stable performance even in harsh environments. Their low self-discharge rate (about 3% per month) ensures reliable energy retention during storage, outperforming many alternatives.

6: Versatile applications

The safety, durability and efficiency of LiFePO4 make it suitable for a variety of uses:

- Electric Vehicles (EV): A top choice for buses, trucks and fleet vehicles due to safety and cycle life. - Renewable energy storage: Ideal for solar and wind energy systems that require daily cycling. - Consumer electronics: Used in portable power stations, drones and medical devices. - Industrial backup power: Suitable for UPS systems and telecommunication infrastructure.

7. Stable voltage output

LiFePO4 batteries provide a stable voltage over most of the discharge cycle, ensuring continuous power delivery. This "flat discharge curve" is critical for applications that require a stable energy output, such as electronic devices or motor drive systems.

Challenges and Trade-offs

While LiFePO4 batteries offer many advantages, they have a lower energy density than nickel-cobalt-based lithium batteries, meaning they can take up more space for the same energy capacity. However, advances in battery design and hybrid systems are easing this limitation.

What is the difference between a generator and an inverter?

Generators and inverters are widely used in modern society, such as solar inverter systems, fuel generators, renewable energy generators, etc. However, many people are not clear about their differences and their respective usage scenarios. Now I will analyze the working principles, differences and application scenarios of generators and inverters, so that everyone can better know which option is more suitable for their application.

Generator

A generator is a device that converts mechanical energy into electrical energy and is widely used in various industrial and civil occasions. The working principle of the generator is based on the principle of electromagnetic induction, that is, the rotating conductor cuts the magnetic lines of force in the magnetic field to generate current. There are many types of generators, mainly including:

DC generator: outputs direct current, suitable for occasions requiring stable current, such as motor drive, charging, etc.

AC generator: outputs alternating current, widely used in power systems, factories, shopping malls and other places.

The main advantages of the generator include high efficiency and stability, and its disadvantages are mainly large size and heavy weight, which are suitable for use in fixed places.

Inverter

An inverter is a device that converts direct current into alternating current. It is commonly used in solar power generation systems, energy storage equipment, electric vehicles and other fields. It relies on existing DC power supplies (such as gel batteries or lithium batteries, solar panels, and vehicle power supplies) and cannot generate electricity independently. The working principle of the inverter is to modulate DC pulses into AC waveforms through a switching circuit. The types of inverters are mainly divided into:

Sine wave inverter: outputs high-quality sinusoidal AC, which is exactly the same as the mains power. It is suitable for equipment with high power requirements, such as home energy storage, farms, medical equipment, and schools.

 Square wave inverter: outputs simple square wave AC, which is suitable for equipment with low power requirements, such as power tools and lamps. Only pure resistive loads (such as incandescent lamps) are supported, which are basically eliminated and only seen in extremely low-cost scenarios.

Modified sine wave inverter: The waveform is a step-like approximation to a sine wave, with low cost, suitable for ordinary resistive loads (such as light bulbs, electric heaters), suitable for low-budget off-grid systems, vehicle power supplies, simple tool power supplies, etc. Disadvantages: May damage inductive loads, cause noise, heat, etc.

The advantages of inverters are that they are small and light, suitable for mobile or temporary use. However, their prices are higher than generators, and their power output is usually lower than similar generators.

Generators are "autonomous power generation equipment" suitable for long-term, high-power power supply, but they rely on fuel.

Inverters are "power conversion equipment" that rely on batteries (gel batteries or lithium batteries) or solar energy and are suitable for clean, quiet and portable power.

The main differences between generators and inverters

GeneratorInverterWorking principleMechanical energy generates electrical energyand direct current is converted into alternating currentApplication scenariosFactories, construction sites, etc.,Solar energy systems, wind power systemsOutput typeProviding DC or ACSpecializing in converting DC into ACSize and portability BulkySuitable for use in fixed locations Smaller and lighterSuitable for portable useEfficiencyHigh efficiencyHigh efficiency

When choosing a generator or inverter, users should consider the following points:

1. Power requirements: First, you need to know how much power you need to provide and choose the right device. 2. Power type: Confirm whether the device requires DC or AC power, and then choose the right device. 3. Usage scenario: Consider the portability, size and weight of the device, and choose the device that is suitable for the specific use occasion. 4. Budget: According to your own financial situation, choose a generator or inverter reasonably to ensure the long-term use value of the equipment. 5. Efficiency and maintenance: Understand the efficiency of the equipment, choose equipment that is easy to maintain and use, and ensure the normal operation of the equipment.

Do solar panels have to be connected to the grid?

Uncertain, whether solar panels need to be connected to the grid depends on which power generation system you choose. There are grid-connected solar systems and off-grid power generation systems. You should choose according to your usage scenario conditions and needs

Grid-connected solar power generation system

The grid-connected power generation system must be connected to the grid, mainly including solar panels, grid-connected inverters, grid-connected cabinets, junction boxes, controllers, and grids. The stability of the grid is very important for the operation of the grid-connected system. When the grid is out of power, the photovoltaic power generation system will also stop working. Therefore, when choosing a grid-connected solar system, places with stable grids can be given priority. If you want to save electricity costs and have convenient power supply, a grid-connected solar power generation system is indeed a good choice

Off-grid solar power generation system

The off-grid solar power generation system is also called an independent solar power generation system. It is a power generation system that can operate independently without connecting to the grid. It mainly includes solar panels, off-grid inverters, batteries, junction boxes and other components. The direct current converted by solar panels through sunlight is converted into alternating current for household use through inverters, and the battery will also store electricity.

How does solar energy work step by step?

The Solar Energy System works in four main steps:

1. Converted into direct current through solar panels

2. The inverter converts direct current into alternating current

3. Powering household loads

4. Extra power is transmitted to the grid or stored in batteries

1. Converted into direct current through solar panels

Solar panels are usually made of silicon, and are divided into types such as monocrystalline silicon, polycrystalline silicon and thin-film batteries. Solar cells are the core of photovoltaic modules, responsible for converting photons in sunlight into electrons to generate direct current

2. The inverter converts direct current into alternating current

Generally, household electricity is alternating current, and direct current cannot be used directly as household electricity. The inverter converts direct current into alternating current through internal electronic circuits (such as IGBT or MOSFET)

3. Powering household loads

The alternating current output by the inverter can provide stable power for household loads such as lights, refrigerators, TVs, and air conditioners

4. Extra power is transmitted to the grid or stored in batteries

The extra power generated throughout the day can be transmitted to the grid and can be used to offset future electricity bills (consult local power companies)

Stored in colloidal batteries or lithium batteries, the battery power can be used when the sunlight is not so sufficient and the power generation is low

In summary, Solar power generation is a green energy that can not only save electricity bills for your family, but also avoid the instability of the city power supply. Solar energy + energy storage, 24-hour uninterrupted power supply. If you need it, please contact SUNCHEES to design the most cost-effective solar system for your home.

Is 10KW solar enough to run a house?

Many customers do not know how to choose the solar energy system for  home use，

The best way is to provide us with your electricity bill, and we will design a suitable system based on the monthly electricity consumption

Sunchees 10KW solar power system with 2pcs 28KWH lithium battery system

 Suitable for daily power consumption : 57KWH

Allowable max loads power : 10KW

Using 2pcs big capacity 51.2V 260Ah LiFePO4 lithium batteries, long lifespan, competitive price. Most supplier use 51.2V 200Ah Lithium battery, but their price is similar as our 260Ah lithium battery.    2. Our 10KW inverter are using large MPPT charging current 120A, MPPT efficiency is up to 99%, allow maximum pv input 7200w solar panels. Most other inverter use 1pc 80A MPPT controller, it only allow maximum pv input 4200w solar panels

If you need more information ,pls contact sunchees solar

Do I still pay for electricity if I have solar panels in the home?

Many customers believe that by installing a solar energy system, they can completely bid farewell to their electricity bills with 100% certainty

This idea is not entirely correct, because truly bidding farewell to electricity bills depends on the configuration of the solar power  system you choose

For example: A 10KW solar power system is with 12 pcs 600W solar panels and 15 solar panels. The difference lies in the sun time , If in sunny areas, we recommend installing 12pcs 600W solar panels that  enough for charge 15KWH lithium batteries.  If there is not enough sunlight for 6 hours a day in an area, we will help customers design a configuration of 15pcs 600W solar panels

If you Say good bye  to electricity bills, there is another important configuration, the capacity of lithium batteries. As an important storage product for solar energy systems, the role of lithium batteries depends on how many hours you can use them

10KW solar system  use 1pc 15KWH lithium battery, this can backup 4-6 hours ,

10KW solar system use 2pcs 30KWH lithium battery ,this can backup 10-12hours

So, say good bye 100% electricity bills, the configuration of solar energy systems is very important

Is it worth having battery storage with solar panels?

You must have encountered this situation in a foreign country , during the hurricane season , Dry season，there is always a power outage ,the food in the refrigerator is spoiled ,and the children can not attend on-line classes ，which is a terrible。

solar panels have emerged as a popular choice for many households and businesses looking to reduce their carbon footprint and energy costs. However, a question that often arises is whether it is truly worth having battery storage in conjunction with solar panels.

 in regions where power outages are common, a solar battery system can act as a reliable backup

 In areas with high electricity bills, it can help families reduce the pressure of electricity bills

Sunchees 10KW solar panel system with 300AH energy storge  lithium battery , complete solar system only 5000USD , this system can working 6-8hours , if you home electricity bill per month is : $300,  The investment cost that you can recover within 2 years

The remaining time is spent using electricity for free. Solar panel life time : 25 years , lithium battery life time : 10 years .

I think solar energy storage is currently the most worthwhile investment, What do you think?

What causes solar inverter alarms?

Solar inverters are important in solar power generation systems. They convert the direct current generated by solar panels into alternating current for home or commercial use. However, during use, the inverter may have various alarm conditions, affecting the normal operation of the system.

Common causes of solar inverter alarms

1. Abnormal DC input voltage

2. Abnormal AC output voltage

3. Overload protection

4. Short circuit protection

5. Overheat protection

6. Abnormal battery voltage

7. Communication failure

1. Abnormal DC input voltage

(1) DC input voltage is too high: When the output voltage of the solar panel exceeds the rated input voltage of the inverter, the inverter will issue an overvoltage alarm. This may be caused by unreasonable configuration of the solar panel or too low rated input voltage of the inverter. Solution: Check the configuration of the solar panel to ensure that its output voltage is within the rated range of the inverter. If the rated input voltage of the inverter is too low, consider replacing the inverter.

(2) DC input voltage is too low: When the output voltage of the solar panel is lower than the starting voltage of the inverter, the inverter will issue an undervoltage alarm. This may be caused by insufficient output power of the solar panel or too high starting voltage of the inverter. Solution: Check the output power of the solar panel to ensure that it meets the starting requirements of the inverter. If the starting voltage of the inverter is too high, you can consider replacing the inverter.

2. Abnormal AC output voltage

(1) AC output voltage is too high: When the AC voltage output by the inverter exceeds the rated voltage, the inverter will issue an overvoltage alarm. This may be caused by grid voltage fluctuations or improper output voltage regulation of the inverter. Solution: Check the grid voltage to ensure that it is within the rated range of the inverter. If the grid voltage fluctuates greatly, consider installing a voltage stabilizer. At the same time, check the output voltage regulation setting of the inverter to ensure that it is correct.

(2) AC output voltage is too low: When the AC voltage output by the inverter is lower than the rated voltage, the inverter will issue an undervoltage alarm. This may be caused by improper output voltage regulation of the inverter or grid voltage fluctuations. Solution: Check the output voltage regulation setting of the inverter to ensure it is correct. If the grid voltage fluctuates greatly, you can consider installing a voltage stabilizer.

3. Overload protection

When the output power of the inverter exceeds the rated power, the inverter will issue an overload alarm. This may be caused by excessive load or too small rated power of the inverter. Solution: Check the size of the load to ensure that it is within the rated power range of the inverter. If the load is too large, you can consider reducing the load or increasing the rated power of the inverter.

4. Short circuit protection

When a short circuit occurs at the output end of the inverter, the inverter will issue a short circuit alarm. This may be caused by a line fault or an internal fault in the inverter. Solution: Check the line to ensure that there is no short circuit. If there is no problem with the line, it may be an internal fault in the inverter, and you need to contact us

5. Overheat protection

When the temperature of the inverter exceeds the rated temperature, the inverter will issue an overheat alarm. This may be caused by too high ambient temperature or poor heat dissipation of the inverter. Solution: Check the ambient temperature to ensure that it is within the rated range of the inverter. If the ambient temperature is too high, you can consider adding heat dissipation equipment. At the same time, check the heat dissipation system of the inverter to ensure that it works properly.

6. Abnormal battery voltage

When the battery voltage exceeds or falls below the rated voltage of the inverter, the inverter will issue an abnormal battery voltage alarm. This may be due to battery aging or improper inverter rated voltage setting. Solution: Check the battery status to ensure that it is in good working condition. If the battery is aging, you can consider replacing the battery. At the same time, check the rated voltage setting of the inverter to ensure that it is correct.

7. Communication failure

When the communication between the inverter and the monitoring system fails, the inverter will issue a communication failure alarm. This may be due to a communication line failure or an internal fault in the inverter. Solution: Check the communication line to ensure that it is not faulty. If there is no problem with the communication line, it may be an internal fault in the inverter and you need to contact us

How many solar panels are required to power a house?

If you are wondering how many solar panels you need to power your home, there are several important factors to consider in order to determine the right amount. Here is a breakdown of the key considerations:

1. House electricity demand:

2. Solar panel power:

3. Light conditions:

4. Calculating the number of panels:

1. House electricity demand:

Start by understanding your household's electricity consumption. Review your electricity bills from the past few months or a year to determine the average daily or monthly usage and the power requirements of your household appliances.

2. Solar panel power:

Solar panels typically have a power range of 500 watts to 600 watts or higher, with 600 watts being the most common. For example, a 600W solar panel can generate 600Wh of electricity per hour under standard lighting conditions.

3. Light conditions:

The amount and intensity of sunlight vary by location and is usually measured in peak sunshine hours. This value indicates the number of hours of sunlight received by each square meter of solar panels in a day under standard test conditions (1000 watts/square meter). A higher peak sunshine hours value means more electricity generation per day.

4. Calculating the number of panels:

Using the data collected, you can calculate the number of solar panels needed. For example, if your household consumes 30kWh of electricity per day and each panel generates 1.2kWh per day, you would need approximately 15 panels. This calculation should also account for system efficiency, typically around 80% to 90%.

It is important to consider factors such as backup power supply, seasonal changes, and weather conditions when determining the number of panels needed to ensure a stable power supply.

I hope this information helps you better understand how many solar panels are required to power your home. If you have any further questions or need assistance, please feel free to reach out.

Explore The Infinite Possibilities Of Solar Energy Systems

In today's era of pursuing sustainable development and clean energy, solar energy systems are changing our energy landscape with their unique charm and huge potential. As an inexhaustible green energy, solar energy has brought many conveniences and opportunities to our lives.

1. Working principle of solar energy system

2. Types of solar energy systems

3. Advantages of solar energy system

4. Application fields of solar energy systems

5. Future Outlook of Solar Energy Systems 

1. Working principle of solar energy system

Solar energy system mainly converts sunlight into electrical energy through the photovoltaic effect. Photovoltaic panels are composed of multiple solar cells. When sunlight shines on the battery, the energy of photons stimulates the movement of electrons, thereby generating electric current. This process is simple and efficient, does not require any moving parts, is almost silent and pollution-free.

For example, common household solar energy systems are usually installed on the roof. When the sun is sufficient, the electricity generated by photovoltaic panels can be directly used by the family, and the excess electricity can be stored in batteries or sold back to the grid.

2. Types of solar energy systems

Independent solar energy system This system is not connected to the grid and relies entirely on solar power generation and stored electricity to meet energy needs. It is usually used in remote areas or places where there is no access to the grid, such as communication base stations in mountainous areas, lighthouses at sea, etc. Grid-connected solar energy system Connected to the power grid, when solar power generation is insufficient, it can obtain electricity from the grid; when solar power generation is excessive, it can feed back excess electricity to the grid. This not only improves the efficiency of energy utilization, but also brings certain economic benefits to users. Hybrid solar energy system Combines solar energy with other energy forms, such as wind power, hydropower or diesel generators, to ensure stable power supply under various weather conditions.

3. Advantages of solar energy system

Environmental protection and energy saving Solar energy is a clean energy that does not produce greenhouse gas emissions, which helps to reduce pollution to the environment and mitigate the impact of climate change. Cost-effectiveness With the advancement of technology and the expansion of scale, the installation and operation costs of solar energy systems are gradually reduced. In the long run, solar power generation can save users a lot of electricity bills. Independence and reliability In some cases, such as when natural disasters cause power grid failures, having an independent solar energy system can ensure basic energy supply and improve the reliability of life.

4. Application fields of solar energy systems

 Household area

Power supply Meet the daily lighting and electrical appliances of the family, such as TV, refrigerator, washing machine, etc., and reduce the cost of household electricity. For example, many families install solar panels on the roof, and the electricity generated is enough to meet most of the electricity demand during the day. Hot water supply Provide hot water for the family through solar water heaters, reducing the dependence on traditional energy water heaters.

 Commercial and industrial areas

Factory production Provide electricity for the factory's machinery, equipment, production lines, etc., reduce production costs, and improve the competitiveness of enterprises. For example, some large manufacturing plants use solar energy systems to meet part of the production electricity, reducing the consumption of city electricity. Office buildings Meet the electricity needs of office buildings such as lighting, air conditioning, and elevators, and create a green office environment. Commercial centers Shopping malls, supermarkets and other commercial places are powered by solar energy systems to achieve energy conservation and emission reduction.

Agricultural field

Irrigation system Use solar energy to drive water pumps for farmland irrigation to ensure the growth of crops. In some arid areas, solar irrigation systems play an important role. Greenhouses Provide the energy required for lighting and temperature regulation for greenhouses to promote the growth of crops. Agricultural product processing Solar energy is used in the processing of agricultural products, such as drying and refrigeration.

IV. Transportation

Solar street lights The street lights on both sides of the road are powered by solar energy, saving energy and reducing maintenance costs. Electric vehicle charging Build solar charging stations to provide charging services for electric vehicles.

V. Communications

Communication base stations Communication base stations in remote areas rely on solar energy systems to ensure smooth communications.

Satellite communications Some equipment on satellites uses solar energy as a source of energy.

VI. Public facilities

Traffic lights Traffic lights in cities are powered by solar energy to improve operational reliability. Outdoor billboards Solar energy provides lighting for outdoor billboards, reducing the trouble of accessing the mains. Public toilets Meet the energy needs of public toilets such as lighting and ventilation.

The application of solar energy systems in various fields continues to expand and deepen, providing strong support for achieving sustainable development goals, responding to energy crises and environmental protection challenges.

5. Future Outlook of Solar Energy Systems

With the continuous innovation and breakthrough of technology, the efficiency of solar energy systems will be further improved and the cost will continue to decrease. The development of new materials and manufacturing processes will make solar cells more efficient, lightweight and durable. At the same time, the combination of solar energy with energy storage technology and smart grid will be closer, providing strong support for global energy transformation.

In short, as a sustainable energy solution, solar energy systems are leading us to a cleaner, greener and better future. Let us actively embrace solar energy and contribute to the sustainable development of the earth.

Home Solar System Installation Steps

Installation Steps Of Sunchees Solar Energy System

1. Choose a suitable installation location

2. Prepare installation materials and tools

3. Install solar panels

4. Connect cables

5. Install inverter and battery pack

6. Test and debug

7. Regular maintenance

It should be noted that the installation of the solar system requires certain skills and experience. If you do not have the relevant knowledge, it is recommended to seek help from professionals. At the same time, during the installation process, strictly follow the instructions and safety specifications to ensure the quality and safety of the installation.

Latest news about the solar energy products

As of September 20, 2024, the solar energy industry continues to show strong growth trends.

In terms of technology, there have been significant advancements in solar panel efficiency. New materials and manufacturing processes are being developed to increase the power output of solar panels while reducing costs. This is enabling more widespread adoption of solar energy in both residential and commercial settings.

In the market, there is an increasing demand for solar energy solutions. Many countries are setting ambitious renewable energy targets, driving the growth of the solar industry. Additionally, businesses and homeowners are recognizing the long-term economic and environmental benefits of solar power and are investing in solar installations.

Research and development efforts are also intensifying. Scientists and engineers are working on innovative storage solutions to address the intermittent nature of solar energy. This includes the development of advanced batteries and other energy storage technologies that can store excess solar power for use when the sun is not shining.

Furthermore, the integration of solar energy with other renewable sources and smart grid technologies is becoming more common. This helps to optimize the use of renewable energy and improve the stability and reliability of the power grid.