it's relative

⁠@@mikelo_GILOga lithium battery is lithium battery,what’s relative?

@@Sixmeji the amount of money you have and the kind of projects you want to use it for that is what is relative. I understand that lithium batteries retains 90% of its energy but every project is unique based on the above reason

@mikelo_GIL Lithium Iron Phosphate (LiFePO4) batteries offer a longer service life and greater efficiency compared to lead-acid batteries. LiFePO4 batteries can last between 5 to 20 years when used and maintained properly, whereas lead-acid batteries typically last for 2 to 5 years. This longevity makes LiFePO4 batteries a more cost-effective investment over time. When it comes to daily usage, LiFePO4 batteries also have a higher usable capacity due to their ability to safely tolerate deeper discharges. For instance, a 100AH LiFePO4 battery can typically be discharged to 80-100% of its capacity without significant impacts on its lifespan, providing about 80 to 100AH of usable energy daily. In contrast, lead-acid batteries are generally recommended to be discharged only up to 50% of their capacity to avoid premature aging, which means a 100AH lead-acid battery would provide around 50AH of usable energy daily. Furthermore, even after years of use, when a LiFePO4 battery's capacity might degrade to 80% of its original capacity, it still offers more usable energy and a longer cycle life compared to a new lead-acid battery. This aspect, along with the reduced efficiency losses and greater depth of discharge capabilities of LiFePO4 batteries, underscores their superior long-term value and performance. It's important to note that while LiFePO4 batteries have a higher upfront cost, their longer lifespan and greater efficiency can lead to cost savings over time, making them a better investment for applications where long-term reliability and low maintenance are critical. In the long run, you spend more buying acid lead batteries.

Pls can I learn from you?

Which one is better??

​@@abokoeguale9783 Lithium is better

Lithium is better but more expensive

Lithium ion battery are better and more efficient but it costly@@abokoeguale9783

Better go for "expensive" battery to have rest of mind ​@@mikolobabz Lithium Iron Phosphate Battery is one of the best after Lithium Polymer Battery. Split Solar System is the best overall because it allows for easy and cheap upgrades in your Solar Electric Power Generation System. Go for Easun 60A 190Vdc max input .

silly

Did you have a chance to watch the video? It's crucial to first determine the total load you wish to support. Before posing your question, I recommend conducting an inventory of all the appliances in your home you intend to power and calculating their combined wattage. Suppose the cumulative wattage of the appliances you plan to power at any given moment is 2000 watts, and your goal is to sustain this load for 12 hours daily. To calculate the energy required, you would multiply 2000 watts by 12 hours, resulting in 24,000 watt-hours (Wh) or 24 kilowatt-hours (kWh). Therefore, you'd need a battery storage capacity of at least 24 kWh. It's advisable to account for a higher capacity to compensate for potential power loss and inefficiencies. Regarding the inverter size, it should be capable of supporting at least 2000 watts continuously. An appropriate inverter capacity might start around 3000 watts to ensure it can handle the load and any surge demands. Furthermore, assuming an average of 5 hours of effective sunlight per day, you would require a solar panel system capable of producing significantly more than your daily consumption to account for inefficiencies and variations in sunlight availability. For a requirement of 24 kWh per day, installing solar panels with a total capacity of at least 4800 watts is advisable. However, considering efficiency losses and potential lower sunlight hours, aiming for around 6500 watts of solar panel capacity would provide a more reliable buffer. In summary, my response to you is very simplified. There are other factors that may affect everything I said. Understand that inverters have a max input voltage and Amps as well, so you may be limited to how many panels or watts you can send from the sun to the inverter. Also, this is specifically for a 48-volt system.

I just figured out you were trolling.

@@meilyn22 lol,calculate d total load of naija

​@@meilyn22 I really like this response and explanation. Welldone sir

I think say na only me dey reason d matter..