Reasons for Buying Solar Panel Kit for Domestic Use

The unwavering quality of a 10KW solar power system additionally gives energy security. Solar system kits make property holders less defenseless against blackouts, guaranteeing a predictable energy supply. Enjoy your off-grind setups and power-full home with our endless collections.

With high power bills and consumption, a 13.3kw solar system is the best option. We provide a wide range of services and the best solutions.

Sustainable Energy for Your Future: 10 kW Solar System Sunshine Coast

In an era where sustainability is paramount, transitioning to renewable energy sources is more important than ever. A 10 kW solar system Sunshine Coast can be the perfect solution for homeowners and businesses looking to reduce their carbon footprint while enjoying significant savings on energy costs. At All Energy HQ, we are dedicated to providing high-quality solar solutions that empower you to embrace a greener future.

Why Choose a 10 kW Solar System?

A 10 kW solar system Sunshine Coast is an ideal choice for medium to large homes or small businesses, providing ample power to meet energy demands. With an average output of 40-50 kWh per day, this system can cover a significant portion of your electricity needs, allowing you to harness the sun's energy efficiently. By choosing a 10 kW system, you can drastically reduce your reliance on the grid and lower your monthly electricity bills.

Cost-Effective Energy Solution

Investing in a 10 kW solar system Sunshine Coast is not only an environmentally friendly choice but also a financially savvy decision. With rising energy prices, solar power offers a stable and predictable energy cost. Additionally, various government incentives and rebates make it easier than ever to offset the initial investment. Over time, the savings on your electricity bills can quickly surpass the cost of the system, providing you with long-term financial benefits.

Environmental Impact and Sustainability

By opting for a 10 kW solar system Sunshine Coast, you contribute to a sustainable future by reducing greenhouse gas emissions. Solar energy is a clean, renewable resource that minimizes your environmental impact. With climate change concerns at the forefront, making the switch to solar power is a proactive step towards protecting our planet for future generations. Your commitment to sustainability not only benefits your home or business but also the wider community and the environment.

Expert Installation and Support

At All Energy HQ, we understand that transitioning to solar power can seem daunting. Our team of experienced professionals is here to guide you through every step of the process, from selecting the right 10 kW solar system Sunshine Coast for your needs to seamless installation. We take pride in providing exceptional customer service and ongoing support, ensuring that you feel confident in your investment.

Start Your Solar Journey Today

Ready to embrace sustainable energy? Contact All Energy HQ today to learn more about our 10 kW solar system Sunshine Coast offerings. Our knowledgeable team will help you navigate your options and create a tailored solar solution that fits your energy needs and budget. Together, we can work towards a brighter, more sustainable future for you and your community. Don’t wait any longer; make the switch to solar and start enjoying the benefits of renewable energy today!

10 KW Solar Panels Price in Brisbane – Quick Solar

Thinking about installing 10 kW solar panels in Brisbane? Choose Quick Solar to brighten up your home with sunshine and cut down on your electricity bills. Enjoy eco-friendly energy and help create a greener planet. Ready to make the switch? Visit our website at Quick Solar and start saving today!

Space Station Concepts: Dual Keel

"The new 'Dual Keel' Station was largely based on Lockheed and McDonnell-Douglas designs and its structure was much stiffer and hence easier to stabilize. It would offer additional space for external instruments plus a better microgravity environment than the previous gravity gradient-stabilized 'Power Tower.' The number of crew members was increased to 8 astronauts because scientists were concerned that a crew of six would be too busy with assembly and maintenance tasks and have no time for research. NASA's target date for the launch of the first element was now January 1993 while the initial operational capability had slipped to January 1994 mainly because the Fiscal 1986 budget was reduced from $280 million to just $200 million.

"McDonnell-Douglas illustration of the 'Dual Keel crew modules.

This McDonnell-Douglas concept drawing depicts a robotic arm controlled by an astronaut. The arm is being used to maneuver a new addition to the space station into place. The robotic arm was to have been essential to building the space station in orbit.”

11 Shuttle flights would be required for initial assembly. Officially, the estimated cost of the Station had only increased by $400 million but there were concerns that NASA was once again hiding the true cost of the larger, more complex 'Dual Keel' design.

“Dual Keel space station – Initial Operational Capability (IOC) Configuration, 11-15-85”

NASA struggled to define a 'Dual Keel' design that met all the various cost, engineering, safety, launch and user requirements. By the time Phase B1 ended in March 1986, the size of the truss structure elements had been increased from 3 x 3 meters to 5 x 5 meters for additional strength and stiffness. Another early 1986 modification involved the power system, which was upgraded to 87.5 kW. By the end of Phase B1 in March 1986, NASA had settled for a hybrid system consisting of 37.5 kW photovoltaic arrays and 50 kW solar thermodynamic generators. The number of American crew modules was also reduced from four to two while European and Japanese laboratories were incorporated in the design for the first time. The habitable volume remained the same, though, since the length of the US modules was increased to 13.3 meters. NASA Space Station Office submitted its recommended final baseline in May 1986 as Phase C/D started. The number of instrument mounting ports was reduced to five, down from an earlier projection of nine. One of the two bays for satellite servicing was also deleted.

According to the May '86 Space Station assembly sequence, the first element would be launched in January 1993. The Station would support man-tended operations after the sixth Shuttle assembly mission in August 1993 and be ready for permanent occupation after the ninth mission in January 1994. Initial Operating Capability (IOC) would be achieved after 21 flights -- twice as many as the 1984 estimate.

By the time of the 'Dual Keel' Space Station's final flight sequence overview in October 1986 NASA had to insert an additional eight Shuttle flights into the manifest. By this time, increased complexity and Shuttle payload capability reductions had increased the required number of assembly flights to more than 30 for an Initial Operating Capability (IOC) vs. 8-10 in 1984.

"The design of the Space Station has undergone the first major configuration change prior to the start of Phase B. The artist’s concept here depicts the updated Dual Keel method which retains many of the basic elements of the previously considered Power Tower concept. The primary difference is the move to favor two vertical booms rather than the Power Tower’s single boom. The dual booms provide additional framework for the attachment of other structures. Pressurized modules have also been moved from the lower area of the Power Tower concept to the Center of gravity. This has been done, NASA officials say, to meet the needs of future space station customers for the best microgravity environment attainable. More refinements are expected in the design as the program works toward the Systems Requirements Review in March of 1986."

NASA's new Space Station design was criticized in a widely publicized astronaut office briefing by Shuttle astronaut Gordon Fullerton. The Dual Keel design was found to provide poor access for maintenance, visibility from habitable areas was obstructed, there was no provision for internal vehicle 'hands on' access to EVA equipment. No crew escape vehicle had been added although a small fleet plus lower-than-hoped-for flight rates means astronauts could not be rescued as easily by the Shuttle. The Canadian manipulator was regarded as insufficient for building and maintaining such a complex Station. Fullerton also criticized excessive EVA 'spacewalk' requirements, including a 'long and complex' assembly sequence. 'Basic structure, wire runs, and plumbing are not easily designed for replacement / repair. EVA crew time even for planned maintenance was excessive. Correction of design errors may not be possible; unplanned failures may not be fixable at all...'

McDonnell-Douglas' redesigned 'Dual Keel' crew modules of this period introduced separate 'node modules' or docking ports which also accommodated many systems that would not have fit inside the original 'Power Tower' crew modules. NASA was still planning to contribute two laboratory modules plus two habitation modules in late 1985. Gordon Fullerton and other observers felt the Station's habitable volume was too limited when the number of US modules was reduced to one lab plus one habitation module. There would be no room for a second shower, commode or 'safe haven' emergency provisions. A Boeing longer 13.3-meter module was introduced in early 1986.

"Display model of Dual Keel Space Station concept (1986); boxy rectangular truss structure with attached modules and extended solar array wings. 1:100 Scale."

The Space Station was briefly suspended by a major row in the summer of 1986 when NASA tried to reassign some habitation module responsibilities from the Johnson Space Center to the Marshall Space Flight Center. A compromise was reached in September 1986, but it was yet another indication of the Station's Byzantine management structure and turf battles between NASA centers. But Congress still approved the project's $420-million Fiscal 1987 budget while imposing a number of restriction: power levels of at least 37.5 kW, fully outfit the microgravity lab by the sixth assembly flight, attach useful science payload by the third flight, launch all US elements before the foreign modules and restrict ESA's Columbus module to life sciences. The congressional requirements would essentially have forced NASA to change the Station along the lines of a new proposal which then, surprisingly, emerged from JSC. NASA had previously testified in Congress that no Station funds were being spent on alternative design studies. Using funding earmarked for alternate assembly sequence research, the Johnson Space Center nonetheless ordered its main contractors (Rockwell and McDonnell-Douglas) to examine a smaller, more compact configuration while keeping NASA headquarters in the dark about it... This caused additional confusion about who was really in charge of the project: NASA headquarters or Johnson.

NASA's first detailed cost assessment in February 1987 revealed the 'Dual Keel' Space Station would cost at least $14.5 billion in 1984 dollars, or $21 billion in current-year dollars. This caused a political uproar in Congress, where many politicians had started to express doubt about the project. However, NASA and Reagan Administration officials reached a compromise in March 1987 which allowed the agency to proceed with a cheaper $12.2-billion Phase One Station. This design initially omitted the $3.4-billion 'Dual Keel' structure and half of the power generators. It was dubbed 'Freedom'.

Article by Marcus Lindroos"

-Information from astronautix.com: link

Date: 1984-86

NASA ID: C-1986-2694, GPN-2003-00110, C-1985-8626, C-1985-8751, S85-42963, S87-38365, 86-H-332, KSC-85C-303, GPN-2003-00110

Mike Acs's Collection: SS23 B

National Air and Space Museum: A20100236000

NM Museum of Space History: DUAL KEEL SPACE STATION-0001, DUAL KEEL SPACE STATION-0002

SDASM Archives: 14_025378

Posted on Flickr by Numbers Station: link

10 KW solar system in Australia

SunSolar Energy is a CEC-accredited solar retailer. We offer one of the best-quality 10 KW solar systems in Australia. Using our residential solar panels lowers your energy bill. Contact SunSolar Energy today to learn more about our residential solar solutions.

Emergency power generators for Ukraine

Emergency power generators for Ukraine 5,000 emergency power generators for the Ukraine are ready for delivery to Ukraine. We have also ordered 13 trucks that will deliver directly to Ukraine, if circumstances allow. The responsible ministry should now release the required payment. Furthermore we had winter tents military hospitals and Generators for hospitals for continuous operation offered. The 20" and 40" containers are also available as generator units. CTS Container Station Energy Self Supported I.e. generators in containers in every power class for continuous operation in hospitals and blocks of flats. Here is just one example: VARIEL container – 6 m, Inside: - backup diesel generator set 5 – 10 kW - diesel tank 500 – 1000 l – GSM technology including batteries - air conditioning unit All the equipment is transportable in the container. plus wind power, Wind turbine - 5 kW plus PV system Solar panels - 3KW in a unit. Peter Koehler

Understanding Solar Panel Installation Cost: What to Expect in Kedron, QLD 4031 | SFR Electrical

Switching to solar energy is a smart, sustainable, and cost-effective choice, but one of the first questions homeowners and businesses often ask is: What is the cost of solar panel installation? At SFR Electrical, we understand that the upfront cost of installing solar panels can feel like a big investment. However, with the right information, you can make an informed decision about whether solar energy is right for you.

In this blog post, we’ll break down the factors that influence solar panel installation cost and provide an overview of what you can expect when you choose SFR Electrical for your solar installation in Kedron, QLD 4031.

Factors That Influence Solar Panel Installation Cost

The cost of solar panel installation can vary depending on several factors. Let’s take a closer look at the key elements that can affect your final price:

1. Size of the System

The size of your solar panel system plays a major role in determining the overall cost. Larger systems with more panels generate more power, but they also come with a higher price tag. A standard home solar system might range from 3 kW to 10 kW, with costs increasing as the system size grows.

Smaller Systems (3 kW – 5 kW): These are ideal for smaller homes or households with lower energy needs. The cost typically ranges from $4,000 to $8,000 (after government rebates).

Larger Systems (6 kW – 10 kW): These are better suited for larger homes or businesses with higher energy consumption. The price for these systems can range from $8,000 to $15,000 or more (after rebates).

2. Type of Solar Panels

Not all solar panels are created equal. The type and efficiency of the panels you choose will impact the overall cost. There are generally three main types of solar panels:

Monocrystalline Panels: These are made from high-quality silicon and are typically the most efficient (and expensive) option. Expect to pay more upfront for monocrystalline panels, but they often offer the best long-term performance.

Polycrystalline Panels: These are a more affordable option and still offer decent efficiency. They tend to be less expensive but may not perform as well over time compared to monocrystalline panels.

Thin-Film Panels: These are generally the most affordable, but they are also less efficient, meaning you'll need more panels to produce the same amount of energy.

3. Inverter Type and Quality

The inverter is a crucial component of your solar power system. It converts the energy produced by your panels into usable electricity for your home or business. There are different types of inverters:

String Inverters: The most common and cost-effective option, but less efficient if panels experience shading.

Microinverters: These are more expensive but offer better performance, especially for homes with shading or complex roof layouts.

The type of inverter you choose will influence your overall installation cost.

4. Roof Condition and Installation Complexity

If your roof requires additional work, such as repairs or reinforcements, the installation cost can increase. Likewise, the complexity of your roof design can affect the amount of time and labour needed for installation. Roofs with a steep pitch, multiple angles, or obstructions like chimneys and skylights will require more effort and time to install, which can increase the cost.

5. Location and Accessibility

The location of your property in Kedron, QLD 4031, can also affect the cost. If your property is hard to access or further away from the solar company's base of operations, transportation and additional setup costs may apply. SFR Electrical works across all of Kedron and surrounding areas, ensuring that installation is as smooth as possible.

6. Government Rebates and Incentives

The Australian Government offers several incentives to help offset the initial costs of installing solar panels. One of the primary programs is the Small-scale Renewable Energy Scheme (SRES), which provides rebates based on the size of your solar system. This can significantly reduce the installation cost, and at SFR Electrical, we can help guide you through the process of applying for these rebates to ensure you get the best deal possible.

7. Ongoing Maintenance & Warranty

While the upfront installation cost is the main concern, it's also important to consider long-term costs. Solar panels generally require minimal maintenance, but it's worth investing in periodic maintenance services to keep your system running at peak performance. The warranty on solar panels typically lasts around 10 to 25 years, providing peace of mind for your investment.

Average Solar Panel Installation Cost in Kedron

Based on the factors above, here is an estimated breakdown of what you might expect to pay for solar panel installation in Kedron, QLD 4031:

3 kW System: Between $4,000 and $6,500 (after rebates)

5 kW System: Between $6,000 and $9,000 (after rebates)

6.6 kW System: Between $7,000 and $10,000 (after rebates)

10 kW System: Between $10,000 and $15,000 (after rebates)

These prices include the cost of the solar panels, inverter, installation labour, and system setup, but may vary depending on the specific needs of your property and system design.

How SFR Electrical Can Help

At SFR Electrical, we are committed to offering affordable and transparent pricing for solar panel installation services. We’ll provide you with a detailed quote tailored to your property, energy needs, and budget. Our team will walk you through every step of the process, from the initial consultation to the installation and beyond. We’ll also help you navigate the available government incentives to ensure you get the best deal possible.

Why Choose SFR Electrical?

Expertise and Experience: Our team has years of experience in solar panel installation, ensuring that your system is installed correctly and efficiently.

Tailored Solutions: We offer custom solutions to suit your specific energy needs and budget.

Licensed and Insured: We are fully licensed and insured, giving you peace of mind that the job will be done right.

Ongoing Support: We offer post-installation support, including system monitoring and maintenance.

Get in Touch for a Solar Panel Installation Quote

If you’re ready to learn more about solar panel installation cost or want a free, no-obligation quote, SFR Electrical is here to help. Our team of professionals is ready to guide you through the process and help you make the switch to solar power.

For more information or to schedule a consultation, please contact us at +61 415 154 274. We look forward to helping you save on energy costs and reduce your environmental impact with high-quality solar panel installation.

Understanding Solar System Sizes in KW

Solar systems are measured in kilowatts (KW), which refers to the amount of electricity generated per hour. The size of a solar system you need depends on several factors, including your energy consumption, roof space, and budget. Common residential sizes range from 3 KW to 10 KW, while commercial systems can be much larger, often exceeding 100 KW.

Top Solar Systems for Residential Use

2 KW Solar System

Ideal For: Small households or apartments with limited energy needs.

Average Energy Production: Approximately 250-300 kWh per month.

Components: Typically includes 9-11 solar panels (depending on the wattage), a solar inverter, and optional battery storage.

Benefits:

Cost-effective for low energy consumption.

Can significantly reduce electricity bills.

5 KW Solar System

Ideal For: Medium-sized households with higher energy demands.

Average Energy Production: Approximately 400-600 kWh per month.

Components: Usually consists of 15-20 solar panels.

Benefits:

Provides a good balance between cost and energy output.

Suitable for households with multiple appliances and higher usage.

10 KW Solar System

Ideal For: Large homes or families with significant energy consumption.

Average Energy Production: Approximately 800-1,200 kWh per month.

Components: Usually comprises 30-40 solar panels.

Benefits:

Provides substantial savings on electricity bills.

Can allow for electric vehicle charging or other high-energy appliances.

Conclusion

Investing in a solar system measured in kilowatts can provide significant benefits, from lowering electricity bills to reducing your carbon footprint. With options ranging from small 2 KW Solar systems for apartments to large 250 KW systems for industrial use,

PM Modi Inaugurates CESL's Solar-Powered EV Charging Carport at Statue of Unity in Kevadia, Gujarat

Gandhinagar, November 1, 2024: Prime Minister Narendra Modi inaugurated the Solar-Powered Electric Vehicle Charging Carport at the Statue of Unity in Kevadia, Gujarat. Developed by Convergence Energy Services Limited (CESL), a subsidiary of Energy Efficiency Services Limited (EESL), under the Ministry of Power, this innovative carport underscores the PM's commitment to advancing clean energy solutions and fostering a green mobility ecosystem nationwide.

With support from the Asian Development Bank (ADB), this state-of-the-art solar carport features bi-facial mono-crystalline solar modules and an advanced Battery Energy Storage System (BESS), marking a substantial stride toward a carbon-neutral future. The carport is equipped with a 50 kWp solar capacity and 200 kWh battery storage, enabling it to charge up to 10 electric vehicles (EVs) with a combination of fast and slow chargers. By generating energy on-site, it promotes energy independence, decreases fossil fuel dependency, and supports long-term sustainability.

Developed with a suite of advanced features, the carport offers app-based vehicle charging and battery monitoring, ensuring users to have real-time information on their vehicle’s charging status. A 24-hour CCTV surveillance system, integrated with app-based monitoring, enhances security for both vehicles and users. Additionally, a designated seating area is provided for drivers to rest comfortably while their EVs charge, making the experience convenient and user-friendly.

Speaking at this achievement, Mr. Vishal Kapoor, MD & CEO CESL said, “The Solar Powered Electric Vehicle Charging Carport represents a significant step towards realising the Honourable Prime Minister’s vision for green mobility. Off-grid solar EV charging stations equipped with BESS will demonstrate the feasibility of renewable energy in powering transportation across diverse settings in India, particularly in remote or grid-challenged areas. By establishing infrastructure that is self-sustaining and eco-friendly, CESL aims to lower socio-economic costs of building infrastructure for charging, making sustainable transportation more affordable & accessible.”

"This project reflects CESL’s dedication to pioneering green innovation and developing scalable, sustainable solutions to drive India’s transition toward a cleaner, greener future. Equipped with 60 kW CCS II fast chargers, AC001, and Type II AC chargers, the carport redefines convenience—powering journeys with clean, renewable energy," Mr. Kapoor added.

The inauguration of this solar carport in Kevadia marks a vital advancement in electric vehicle infrastructure across India. By adopting renewable energy and cutting-edge technology, CESL aligns with Hon’ble Prime Minister’s ambitious sustainability goals and stands ready to contribute meaningfully to India’s green energy landscape, promoting cleaner, more efficient transportation alternatives for a sustainable tomorrow.

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A 10.3kW solar panel system is capable of powering all the appliances in a large home with five or more bedrooms, including lighting fixtures televisions, computers, refrigerators and washing machines. Not only that, but it can also provide enough energy to power an air conditioning unit and pool pump.

Guide to Calculating the Area Required for Home Solar Panel Installation

If you are looking to invest in solar energy, you know that it takes a significant amount to install a solar system. Also, it can work approximately 25 - 30 years after installation. Therefore, it is a long-term investment for you and you cannot change the position of solar panels once installed.

So, an accurate calculation of the required surface for the solar panels is extremely important during solar installation in home. Here you need to follow some pointers such as energy consumption, sizing of solar panels, roof orientation, shading, panel wattage, etc. You will get a clear idea that help you to estimate the required surface area for your solar system. Read it carefully to make an informed decision.

5 Steps to Calculate Area for a Solar Installation in Home

These are the simple steps to get the estimation of the required area of a solar system: 1) Calculate the Energy Consumption in Your Home

Check the electricity bills from the past year and check the average monthly and annual electricity consumption in your home. In case, you have some planning to buy new appliances such as a refrigerator, AC, etc., you can add an estimated usage with your calculation.

Example: In case, your average monthly household energy consumption is 750 kWh, then your annual energy requirement is 750 kWh x 12 = 900 kWh. Calculate it before you opt for solar installation in home. 2) Find the Required Solar System Size

To find the required size of your solar system, you have to divide the annual energy required by the average peak sun hours based on your location. Thus you will find the required solar system size in kW.

Example: For instance, your location has 6 peak sun hours every day. Therefore to fulfil your requirement, your solar system size will be = 900 kWh / (6 hours/day x 365 days/year) = 5 kW solar system.

3) Calculate the Number of Solar Panels for Your Solar System

Generally, the energy output of mono-PERC solar panels is approximately 540W. Now you can get the no of solar panels required by dividing it with your solar system size.

Example: In the case of a 5 kW solar system, it requires 9 - 10 solar panels.

4) Measure the Available Space in Your Rooftop

Now, go to your rooftop and measure the width and length of the specific section you want to use for the solar system installation. For this reason, you should choose a space free from obstacles such as vents, chimneys, etc.

5) Find the Required Area For Your Solar System

Consider a standard solar panel with a power output of 540 W. Now the width is 113.30 (cm) & height is 227.20 (cm). Then the area required for a single solar panel is = ((113.30 x 227.20) cm2 /100)m2 = 2.57m2

As per the previous example, if you install 10 solar panels, the total area required will be = 2.57m2  x 10 = 25.7 m2.

Now, using the above step-by-step calculation, you can easily find the required space for your home solar system installation. In case, you are still confused, you may contact a solar system installer such as Das Energie Private Limited. Here you will get free guidance and solar quotations that will help you make an informed decision.

4 Important Factors to Consider During Solar Panel Installation

Here are some other factors, you need to consider for your home solar panel installation to get a hassle-free installation:

1) Calculate Your Budget

Even if you find the correct size of the solar system required in the above method, you may need to calculate how much can you pay for a solar system. In case, you don’t have that much amount, you may choose a lower capacity. Otherwise, you may opt for EMI options to pay the it in different parts of your solar system installer allows you. If you contact professional installers, they will tell you the solar system for the home price after a thorough site visit.

2) Proper Positioning, Direction & Angle

As the solar system is an investment for you, you must focus on getting the maximum output from your solar system. To do so, ask your solar installer to set the solar panels in a shadow-free area. Also, ask them to set it to the best direction and tilt angle to get the maximum energy generation.

3) Consider Solar Subsidy

The central government is offering solar panel installation subsidy of up to Rs. 78,000 on new installations. To get the amount you need to follow all the MNRE guidelines as mentioned. You need to be careful while selecting the solar installer, and its components.

You can get help from Das Energie, where all the solar installers are DISCOM registered and follow all the guidelines. Also, in case you want any help during the online application process, you will get it free of cost.

4) Add Power Backup System

In case, you want to save the excess electricity to use during power cuts, you can add solar batteries to your system. However, it may add additional cost for the batteries and also require additional space. Power backup systems are available only with hybrid and off-grid solar system.

Example of Rooftop Area and Savings Calculation on 5 kW Solar System

Annual Energy Consumption = 900 kWh

Average Peak Sun Hours/Day = 6 hours

Required System Size = 5 kW

Panel Wattage = 540 W

Number of Panels Required = 10 panels

Panel Dimensions = 57m2 per panel

Total Surface Area Required = 7 m2

Optimal Roof Orientation = South-facing

Estimated Cost (without incentives) =

On-Grid:2,90,000 to Rs.3,30,000

Off-grid: 4,40,500 to Rs. 5,13,000

Hybrid: 4,45,500 to Rs. 5,18,000

Solar Subsidy = Rs. 78,000 (PM Surya Ghar Muft Bijli Yojana)

Price After (including Solar Subsidy) = 2,12,000 to Rs. 2,52,000

Note- This PM Surya Ghar solar subsidy scheme is applicable only to on-grid/grid-connected solar systems.

You just read one of the most easy ways to find the required area for home solar panel installation. In case, you are still confused, you can contact Das Energie, where you will get free advice from the solar experts. You can also request a free solar quotation by telling your requirements.

Here you will get every type of solar service such as solar installation in homes, housing societies, and commercial & industrial spaces. Also, your solar system will be installed with high-quality solar components from experienced solar installers.

The Cost of Solar Panel Installation: A Complete Guide to Understanding Your Investment

Solar energy investment has now become more fashionable as everyone seeks a means of providing sustainable and economic energy supplies. One major question however is the price of the installation of the solar panel. The increased technology coupled with government incentives has also made it even cheaper for people to opt for installation of solar panels. Below are the reasons that impact the cost of the investment, potential saving, and tips on the optimization of your solar investment.

1. What Influences the Cost of Solar Panel Installation?

Costing many elements of the solar panel installation, it also depends upon the system size, the complexity of installation, local regulations, and quality of equipment.

System Size: Larger the size, the cottier will be. For instance, if you compare a 1 kW system with a 5 kW system, definitely, the former is going to cost less. Your energy demand determines the size you go for. Type of Solar Panel: In the case of various kinds of solar panels, different efficiencies and prices come forth. Monocrystalline panels are expensive and hence more efficient, and in comparison, polycrystalline panels cost less. Complexity of installation: The complexity of roof installation can also be affected by the type of roofing and the structure of the roof. Flats would be easier and more inexpensive to install on a roof compared to sloped roofs or an intricate design. Inverter and Battery Expensive: Inverter is something that converts solar energy into usable power. The cost varies with its model (string, micro, or hybrid). Batteries act as a storage medium hence add to the costs and enhance the energy independence of the house. Labor and Permit Costs: The labors are geographically vary in prices, as the permit charges are levied by the authorities of local governments also, which form a part of the added costs.

2. Breakdown of Solar Installation Costs by Type of System

The solar installations can be categorized into three types: grid-tied, off-grid, and hybrid systems. It depends on the type of system to determine the cost of installation.

Grid-Tied System: This is the most common type and, therefore, the cheapest in most cases. Since there are no batteries required, grid-tied systems range between ₹40,000 to ₹50,000 per kW. Off-grid system: It is feasible for remote areas. The overall cost will be in the range of ₹60,000 to ₹80,000 per kW considering energy storage in the form of batteries. Hybrid System: A hybrid system provides the best of both worlds with energy storage and grid connectivity, however is a bit costlier around ₹70,000 to ₹90,000 per kW.

3. Average Cost of Solar Panel Installation in India

In India, the cost of solar installation is among the lowest globally, thanks to various government initiatives and the availability of local manufacturers. Here’s an approximate breakdown of cost by system size:

1 kW System: ₹40,000 - ₹50,000

3 kW System: ₹1,20,000 - ₹1,50,000

5 kW System: ₹2,00,000 - ₹2,50,000

10 kW System: ₹3,80,000 - ₹4,50,000

4. Government Subsidies and Incentives to Reduce Installation Costs

The Indian government, under the Ministry of New and Renewable Energy (MNRE), provides several subsidies for promoting the use of solar. This subsidy, in particular in residential systems, can be as low as 30-40 percent based on state-level policies and system size

Central Financial Assistance: It is a subsidy provided by MNRE to the residential consumers on grid-tie solar system installations. This reduces per kW cost and makes installation feasible for domestic consumers. State Subsidies: Several states also have added schemes for incentives. For instance, the rate has gone down in all such plans in Maharashtra, Gujarat, and Rajasthan. Tax benefits: Commercial users also include the benefit of Accelerated Depreciation. Businesses reduce taxable income from the depreciation of the solar asset.

5. Financial Benefits of Solar Panel Installation

Although the installation cost looks to be very high initially, solar power has long-term financial benefits:

Savings in Electricity Bills: The electricity bill is reduced a lot with the solar power system. For residential systems, savings can reach up to 90%. Return on Investment: Normal payback times for a solar system vary between 3 to 5 years, depending on the size of the system and the amount of energy consumed. Add-on property value: Solar panels add value to the property since many homebuyers would be willing to pay extra for the house with the solar panels. With regard to the tax savings benefits, the businesses can realize savings with regard to costs and higher returns on investments.

6. Cost Comparison of Solar Installation Across Different States

The cost of installing solar panels depends on the state due to regional subsidies, labor charge, and energy consumption rate. Here's a comparison of the costs of installing solar panels in a few key states:

Maharashtra: ₹42,000 per kW on average and state subsidies that bring installation costs down. Gujarat: About ₹40,000 per kW, and the state has sound subsidy programs. Rajasthan: Leader in the adoption of solar power, with costs averaging ₹41,000 per kW. Installation cost is nearly 45,000 more costly per kilowatt from other states, but offsets the benefit of stronger policies for net metering at this state.

7. Steps to Calculate Your Solar Installation Cost

Here is the simplified process to estimate your solar installation costs:

Step 1: Determine your energy requirements by reviewing your electricity bills. Step 2. This size of a solar electric system depends upon one's average daily load to energy usage. So mostly house units require 3kw up to 5-kW sizes, as these need higher sizes systems due to higher energy consuming requirement commercial setups. Step 3: Find out available subsidies and incentives and what can be availed in your area. Step 4: Seek quotes from a few installers and compare offers.

8. Hidden Costs to Watch Out For

Most costs are a one-off, but among those:

Maintenance and Repairs: although solar panels entail very minimal maintenance, an occurrence of an occasional cleaning and a minor repair can attract some lifetime costs. Replacement Costs: The inverters usually last for up to 10-15 years and thus incur another cost upon replacement. Inspection and Permits: Another cost could be the inspection and permit fees, which vary from state to state.

9. How Much Can You Save with Solar?

Here, the saving potential with solar installations is highly significant. The average satisfaction of electricity of a household by a solar power system is around 80-90%. The summative savings on electricity will indeed be huge if we take into consideration the lifespan of the solar panel system, which usually lasts for 25 to 30 years. Several cases have seen users return within the first five years, and then start experiencing energy savings.

10. Tips for Lowering Solar Panel Installation Costs

Shop Around: Get competing quotes from multiple installers to find the lowest installed rate. High Efficiency Panels: Higher initial installation, but produce more kilowatt-hours per installation - potentially saving on future added panels. Net Metering: Many states allow and require net metering plans under which the utility credit toward your monthly energy bill excess production. Take Advantage of Subsidies and Tax Credits: Perhaps the best way to come down on your overall cost of installation is by government subsidy and tax incentives.

Finding the Right Solar Installer Selecting an appropriate installer will ensure value for money for your money. Here are a couple of tips for you in this regard. Research and Reviews: Seek installers with good customer reviews as well as good portfolios. Experience with Local Permits and Incentives: Experience will direct the installation so that you get the benefits of their knowledge of local permits and their knowledge of all available and eligible subsidies. Warranty and After-Sales Service: The company should agree to give you the warranty on equipment as well as workmanship. When the after-sales service becomes good, then the amount the customer saves for repairing as well as maintenance becomes important. Conclusion Now it becomes easy for a reader to understand what goes around the cost of installation related to solar panel. With this knowledge, he makes an informed investment in this endeavor. All these work together to choose what suits your specific energy needs and budget in decisions you make about your size of system, installation complexity, subsidies, and financial benefits. The improved affordability and accessibility of solar energy mean the time for a sound investment in this sustainable solution is better than ever. Solar power can save an immense amount long-term from the initial installation of the system.

Whether as a result of environmental pressure, energy independence, or long-term savings drives, the installation of solar panels represents a very powerful step towards a brighter and greener future.

Quick Solar 13kW System - Contact or Visit for Details!

Looking to power up your property with a robust solar solution? Explore Quick Solar's exceptional 13kW solar system in Brisbane! Contact us today at 1300 969 557 OR visit us now at Quick Solar - 13kW Solar System Brisbane to schedule your complimentary consultation and discover the benefits of installing Quick Solar's 13kW solar system for your home or business. 

How To Choose Inverter Size?

The selection of a solar system has always been a concern for everyone. As the heart of the solar system, choosing the correct inverter size is very important.

When deciding on the inverter size, the following points are key:

1.Total Load Power: For inverters with resistive or capacitive loads, selecting the rated capacity is relatively simple. For example, if your total load power is 10 kw, we recommend an inverter with a power size of 11 to 12.5 kw (1.2 to 1.5 times the total load power).

2. Inductive Loads: If the main load is inductive, such as motors, refrigerators, air conditioners, washing machines, or high-power water pumps, the inverter size must be about 3 to 5 times the total power of the inductive load. Inductive loads have high surge power when they start, requiring larger current and starting power. For example, if your inductive load is a 15 kw three-phase water pump and the total power of other loads is 2.5 kw, we suggest choosing a three-phase inverter of 30 to 45 kw.

These are the key points to consider. If you're unsure about selecting the right inverter size, feel free to leave a message on our website or contact us by phone.

The Best EV Chargers For Home Use

There are a number of smart home chargers on the Australian market. Here are my top picks based on installer experience and product reliability.

Goodwe’s HCA series launched in 2022 and is compatible with all EV brands. It allows for smart solar charging and is available in single-phase (7 kW) and threephase (12/22 kW). It also comes with an extended warranty backed by an office in Australia.

Level 2

Most ev chargers come with a standard 10 Amp Type 2 plug for AC charging at home and at public stations. There are also adaptors available to enable your EV to charge with other types of plugs.

Most people will charge their EV at Level 1 public chargers, usually located in shopping centres and restaurants. These can add a full charge overnight for most small to medium battery EVs but will not be fast enough for the average daily commute or road trip.

Installing a Level 2 charger at home is the best long-term solution to increase your EV range and save money on fuel. However, it will cost between $1,000 and $3,000 including installation by a licensed electrician. Look for a charger that features a cable management system that enables you to coil and hang the cables off the connector, out of the way when parking the car. This will keep them away from the elements and help prevent damage.

Level 3

Slow AC charging using a standard 240-volt Australian household outlet can replenish most EVs’ driving range overnight. It’s cheaper than fast DC charging and generates less heat, which is better for battery longevity. This is the most common option for charging at home and can also be used as a backup in the event of long commutes.

A single-phase 7kW EV charger at home can guarantee enough range to get most people to work and back again the next day. Combined with solar power, this can reduce charging costs even further.

Choosing a charger that’s designed for Australia’s climate is important. Having the same provider for both the charger and installation can simplify warranty claims if anything goes wrong. The UK-made Zappi V2 charger from Myenergi and EVSwitch is a great choice. It comes with a 7kW home charger and 5m Type 2 cable, features three modes for maximum efficiency and uses renewable energy whenever possible. It also has an easy-to-use free EV Charging app for remote management, monitoring and scheduling.

Combo

Electric Vehicles (EV) are here to stay and are transforming the way we travel across Australia. However, the EV revolution raises many questions about charging times, driving ranges, and how to find public chargers across the country.

For a stress-free trip, an EV owner needs to ensure that their home charger can keep up with charging demands. Look for a home EV charger with Wi-Fi connectivity, which makes it easy to monitor usage and receive notifications. A good EV charger will also feature enhanced load balancing, which adjusts the power distribution to prevent circuit overload.

When shopping for a home charger, look for one that is compatible with your electricity tariff, solar system, and battery. The Wattpilot EV Charger costs about $1,800before installation and integrates seamlessly with Fronius inverters. It is available as both a hardwired and portable option and features fast charging. The best ev chargers Australia are rated for reliability and come with a 5-year warranty.

Solar

We've rated the best chargers available for home use based on their features, reliability and pricing. Level 2 charging at home is more expensive but offers much faster charging and the ability to co-ordinate with your solar system and home battery to maximise savings. A garage or off-street parking is required to install a level 2 charger at your house.

ABB’s EV chargers are available in 7kW single phase and 22kW three-phase for home and business use. They can be tethered or untethered and come with an EV cable. ABB's EV chargers can be supplied and installed by your Enphase Energy microinverter installer as part of a new solar system or retrofitted to existing systems.

SMA offer an EV charger that integrates with their microinverters (both older and newer models). This smart feature monitors how much excess solar you're exporting and diverts the surplus to your car battery to charge your vehicle using the cheapest electricity in Australia: behind-the-meter Australian solar.