CNBM 5000W Solar Home System Roof System Solar Energy

CNBM 5000W Solar Home System Roof System Solar Energy System 1

CNBM 5000W Solar Home System Roof System Solar Energy

Ref Price:: $6,496.00 / pc

Loading Port:: Shanghai

Payment Terms:: TT or LC

Min Order Qty:: 1 pc

Supply Capability:: 30000 pc/month

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Working Principle of Solar Home System

The stand alone Solar Home System is an off-grid solar system which uses batteries to store the solar energy. Stand alone solar system solutions design for those who are not able or willing to connect to electricity grid.

However, our on-grid solar home system can be connected to the grid for utilization of grid electricity power. Our solar system can add relative equipment as our customer’s requirement which have the function of switching to city electricity automatically. The solar system can use battery power in priority, if sunshine is not so good or loads consumption is too high which cause battery power insufficient. Then system can switch automatically to grid power supply. Meanwhile, the system can charge the batteries with grid power until batteries are fully charged. Then the solar system will switch back to battery power supply.

CNBM Solar Home System Roof System Capacity-5000W

Product Details of Solar Home System

CNBM Solar Home System Roof System Capacity-5000W

Specification of Solar Home System

Technical data:
Inverter	Rated load power					5000W
	Output wave					Pure sine wave
	Input voltage					110V
	Output voltage					DC:12V AC:110V/220V
	Output frequency					50HZ/60HZ
	Precision of output frequency					±6%
Solar panel	Pmax					180W*28PCS
	Vmp					36V47
	Imp					52.5A
Charger controller	Charger voltage & current					110V/60A
Battery	Capacity					12V/150AH*16PCS
support	Aluminium					4PCS/SET*7
Power box	Spray paint iron box,with input,output, ammeter,voltmeter,master switch and so on.
Package data:
Part	Size (LWH mm)				Weight (kg)	20' (pcs)		40' (pcs)
Power box	840620150				140
Solar panel	1610830100*(6ctns)				180
Battery	1100520650*2				1200
Loading electrical equipment(For consulting)
Name of Load		Power(W)	Quantity	Working Time per Day (H)			Working Days
Color TV		65W	2	6			3 days
Satellite TV Receivers		25W	2	6			3 days
lamp		11W	8	8			3 days
Computer		150 W	2	6			3 days
FAN		60W	4	6			3 days
Other		3000W	1	6			3 days

Advantage of Our Solar Home System

1 Excellent Performance: Our Solar Home System is composed by Brand Standard Kits with high quality. Our solar system has the advantage of high efficiency and stable operation. We can ensure our product with a long life period.

2. Small Orders Accepted: We can accept small orders as our customer’s trial order.

3. Warehouse: We have warehouse overseas which can bring great convenience to our customer to pick up the products.

Q:What is the role of solar-powered ventilation systems in solar energy systems?: The role of solar-powered ventilation systems in solar energy systems is to improve energy efficiency and enhance indoor air quality. These systems use solar energy to power fans or vents, which help circulate air and remove excess heat or moisture from buildings. By utilizing renewable energy, solar-powered ventilation systems reduce reliance on traditional power sources and contribute to a more sustainable and eco-friendly approach to cooling and ventilating spaces.

Q:What is the role of optimizers in a solar energy system?: The main function of optimizers in a solar energy system is to maximize the efficiency and performance of the system as a whole. These are electronic devices that are connected to each solar panel individually in order to monitor and optimize its output. Optimizers work by carrying out various tasks. Firstly, they make sure that each solar panel operates at its highest power point (MPP), which is the point where it generates the most power. By continuously tracking and adjusting the voltage and current of each panel, optimizers ensure that they always operate at their MPP, even in situations where shading or other factors may cause some panels to underperform. Additionally, optimizers also offer monitoring and diagnostics at the module level. They gather data on the performance of each panel, including voltage, current, and temperature. This data is then transmitted to a central monitoring system, which allows for real-time detection and troubleshooting of any issues or malfunctions. This detailed insight into the performance of each panel helps to enhance maintenance and overall system reliability. Moreover, optimizers also improve the safety of the solar energy system. They come equipped with built-in safety features, such as rapid shutdown capabilities, that enable the system to quickly and safely shut down in emergency situations or during maintenance requirements. This ensures the protection of both the system and the individuals working on it. In conclusion, optimizers play a crucial role in a solar energy system by maximizing energy production, improving overall efficiency, ensuring safety, and facilitating effective monitoring and maintenance. By optimizing the performance of each individual solar panel, optimizers contribute to the overall success and viability of solar energy systems.

Q:What is the expected return on investment for a solar energy system?: The return on investment (ROI) for a solar energy system can vary based on several factors, such as the initial cost, location, available incentives, and energy usage. Typically, solar energy systems are expected to yield a positive ROI over their lifespan. Installing a solar energy system involves a significant upfront investment, including expenses for solar panels, inverters, and installation. However, the decreasing costs of solar technology in recent years have made the initial expense more affordable. The location of the solar energy system is crucial in determining the expected ROI. Areas with higher solar irradiance and longer sunshine hours tend to generate more electricity, resulting in a higher ROI. Additionally, net metering policies that allow excess electricity to be credited back to the owner can further boost the ROI. Government incentives and subsidies can have a significant impact on the expected ROI. Many countries provide tax credits, grants, and rebates to promote the adoption of solar energy systems. These incentives reduce the initial cost and expedite the payback period, thus enhancing the overall ROI. Furthermore, the energy usage of the property plays a critical role in determining the expected ROI. Higher electricity consumption offers more opportunities for the solar energy system to offset utility bills, resulting in greater savings and an improved ROI. While the specific ROI can vary, studies indicate that solar energy systems typically recoup their costs within 5 to 10 years and continue to generate free electricity for several decades. This extensive period of energy production allows for substantial savings on utility bills and a positive ROI over the system's lifetime. In summary, investing in a solar energy system can provide long-term financial benefits, including reduced electricity costs, potential revenue from excess electricity generation, and increased property value. Conducting a comprehensive evaluation considering the aforementioned factors is crucial in determining the expected ROI for a solar energy system in a specific scenario.

Q:How does the size of a solar energy system affect its cost?: The cost of a solar energy system is influenced by its size. In general, the larger the system, the more it will cost. Several factors determine the cost, including the number of solar panels, the type and quality of the panels, the capacity of the inverter, the mounting equipment, and the labor required for installation. The number of solar panels is a crucial factor in calculating the cost. Solar panels are the primary source of energy generation in a solar system. The more panels you install, the more energy the system will produce. However, each additional panel adds to the overall cost, including the cost of the panel itself, the additional wiring, the mounting hardware, and the labor needed for installation. Another factor to consider is the type and quality of the solar panels. Different panels have varying efficiencies, durability, and warranties. Higher-quality panels with better efficiency are typically more expensive. However, they often come with longer warranties and can generate more electricity over their lifespan, resulting in greater overall savings. The capacity of the inverter is also important in determining the cost. Inverters convert the direct current from the solar panels into alternating current that can be used to power household appliances. Larger solar systems usually require larger inverters to handle the increased energy production. Higher capacity inverters come at a higher cost, which contributes to the overall system cost. The cost is also affected by the mounting equipment and labor required for installation. Larger systems may require more mounting equipment, such as racks and brackets, to securely hold the solar panels. Furthermore, the labor cost for installation increases with the system's size because it takes more time and effort to install a larger number of panels. It is worth noting that although a larger solar energy system may have a higher upfront cost, it can lead to greater long-term savings by reducing electricity bills. A larger system generates more electricity, potentially offsetting a greater portion of your energy needs and reducing your reliance on grid electricity. In conclusion, the size of a solar energy system directly influences its cost. The number of panels, type and quality of panels, inverter capacity, mounting equipment, and installation labor all contribute to the overall cost. It is crucial to carefully consider your energy needs and budget when determining the appropriate size of a solar energy system for your specific requirements.

Q:Can solar energy systems be leased or financed?: Yes, solar energy systems can be leased or financed. Leasing allows homeowners or businesses to use solar panels without owning them, while financing options such as loans or power purchase agreements (PPAs) provide a way to pay for solar installations over time. This makes solar energy more accessible and affordable for a wider range of people and organizations.

Q:Can solar energy systems be used for powering off-grid research facilities?: Yes, solar energy systems can certainly be used for powering off-grid research facilities. Solar panels can be installed to generate electricity from sunlight, which can then be used to power various equipment and systems in research facilities. This renewable and sustainable energy source offers a reliable and cost-effective solution, especially in remote locations where access to traditional power grids may be limited or non-existent. Additionally, solar energy systems can be combined with energy storage solutions, such as batteries, to ensure uninterrupted power supply even during periods of low sunlight or at night.

Q:Can solar energy systems be used for powering financial institutions or banks?: Certainly, financial institutions and banks can utilize solar energy systems to power their operations. In fact, many of these institutions have already embraced solar energy as a means to meet their energy requirements. Solar energy systems offer a dependable and environmentally friendly source of electricity, diminishing their reliance on conventional fossil fuels and lessening their carbon footprint. Typically, financial institutions and banks possess large buildings with substantial energy consumption due to the numerous electronic devices, lighting, and HVAC systems necessary for their functioning. By installing solar panels on rooftops or nearby areas, these institutions can generate a substantial amount of electricity to satisfy their energy demands. Furthermore, solar energy systems can aid financial institutions and banks in reducing their long-term energy expenses. While the initial investment may be higher compared to conventional energy sources, the savings accrued from decreased electricity bills over time can offset the initial costs. Consequently, this can result in significant financial advantages for these institutions, contributing to their overall sustainability and profitability. Additionally, the utilization of solar energy can enhance the reputation of financial institutions and banks by demonstrating their commitment to environmental sustainability and renewable energy. This can attract environmentally conscious customers and investors who value businesses that prioritize eco-friendly practices. Moreover, solar energy systems can furnish a reliable power supply to financial institutions and banks, ensuring uninterrupted operations even during power outages or grid failures. This is especially critical for institutions that handle sensitive financial transactions and necessitate a continuous power supply to maintain data security and operational stability. In summary, solar energy systems can effectively power financial institutions and banks, providing a sustainable and cost-effective solution to meet their energy needs. By embracing solar energy, these institutions can mitigate their environmental impact, reduce energy costs, enhance their reputation, and guarantee reliable operations.

Q:Can solar energy systems be used for powering industrial manufacturing plants?: Yes, solar energy systems can be used for powering industrial manufacturing plants. In fact, many industrial manufacturing plants across the world are already utilizing solar energy systems to reduce their reliance on fossil fuels and decrease their environmental impact. Solar energy systems consist of photovoltaic (PV) panels that convert sunlight into electricity. These panels can be installed on the roofs or open spaces of manufacturing plants to harness the abundant solar energy. The electricity generated by the solar panels can be used to power various processes and equipment within the industrial plant, such as machinery, lighting, heating, ventilation, and air conditioning systems. The use of solar energy for powering industrial manufacturing plants offers numerous benefits. Firstly, solar power is a renewable and clean source of energy, which helps reduce greenhouse gas emissions and dependence on fossil fuels. This aligns with the growing need for sustainable practices and reducing the carbon footprint of industries. Secondly, solar energy systems can significantly reduce electricity costs for manufacturing plants. Once the initial investment is made to install the solar panels, the operational costs are relatively low. Additionally, some countries offer incentives and subsidies for implementing solar energy systems, further reducing the financial burden. Moreover, solar energy systems can provide a stable and reliable source of electricity. With advancements in battery storage technology, excess solar energy can be stored and used during non-sunlight hours or in times of high demand. This helps ensure uninterrupted power supply and reduces the reliance on the grid. However, it is important to note that the feasibility of using solar energy systems for powering industrial manufacturing plants depends on various factors, such as the availability of sunlight, the size of the plant, energy requirements, and the initial investment cost. Additionally, some manufacturing processes may require a consistent and higher level of electricity that may not be fully met by solar energy alone. Overall, solar energy systems have proven to be a viable and sustainable option for powering industrial manufacturing plants. Their use can contribute to reducing carbon emissions, lowering electricity costs, and promoting a greener and more environmentally friendly industrial sector.

Q:Can solar energy systems be used for powering water pumps?: Yes, solar energy systems can be used to power water pumps. Solar-powered water pumps use photovoltaic panels to convert sunlight into electricity, which can then be used to operate the pump. This makes solar energy an environmentally friendly and cost-effective solution for pumping water in remote areas or off-grid locations.

Q:Can a solar energy system withstand extreme weather conditions?: Certainly, extreme weather conditions pose no challenge for a solar energy system. Solar panels boast a sturdy design that enables them to endure diverse weather phenomena, such as scorching heat, freezing cold, fierce winds, heavy downpours, and even snowfall. These panels are crafted with tempered glass and often undergo rigorous testing to ensure their resilience against hailstorms or excessive snow loads. Moreover, solar panels are securely installed to withstand powerful gusts and are engineered to resist corrosion. In essence, although extreme weather conditions may slightly affect solar energy production, solar energy systems are purposefully constructed to persist and function optimally in various weather conditions.

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