Our friends at FMCA are breaking down the different types of batteries for an RV. Check them out below.
Options include lead-acid and lithium-ion, as well as a choice between 6-volt and 12-volt. The 12-volt-DC electrical system is one of the primary lifelines of an RV. The source of that power can involve some combination of generator, shore power, solar energy, and batteries, as well as the converter and the inverter/charger. Here, our focus is batteries, and the possible choices.
This is the next step in the evolution of batteries. Silica dust is added to the electrolyte of these batteries to create a thick gel. Because the electrolyte is much more viscous, it cannot readily leak or spill. Gel-cell batteries have more stringent charging requirements than AGM batteries. Since the advent of AGM, gel-cell batteries have become rare in RVs.
Absorbed Glass Mat (AGM)
These batteries go one step further than gel by absorbing the electrolyte into fine fiberglass pads. The pads can be flat, resulting in standard lead-acid battery size and shape, or they can be rolled into cylinders for a smaller battery footprint. Since the electrolyte of AGM batteries is fully absorbed into mats, the batteries are leak-proof and spill-proof, short of major damage to the battery casing. AGM batteries are not subject to the same charging restrictions as gel batteries, so, generally, standard RV charging equipment can be used without modification. Some high-end converters and inverter/chargers have charge settings for AGM batteries, which have charging curves that differ slightly from those of flooded batteries. As with gel batteries, external corrosion is nonexistent with AGM batteries. In addition, gel and AGM batteries are much less prone to sulfation. And internal resistance is much lower in AGM batteries than in flooded cells, so AGM charging time is much shorter.
Although lithium-ion (Li-ion or Li+) battery technology has been around since the 1980s, historically it has been used in smaller consumer devices such as cell phones and laptop computers. With recent advances, the batteries now can work in larger applications such as RVs and standby power plants. They are a marked departure from their lead-acid counterparts. Comparing the energy density between lithium-ion and lead-acid batteries reveals stark differences. A lead-acid battery can store about 25 watt-hours per kilogram of battery, whereas a lithium-ion battery can store 100 to 265 watt-hours per kilogram. This results in a 50 percent to 70 percent weight savings per amp-hour over a lead-acid battery of the same size. Lithium-ion batteries also have absolutely no discharge memory, so they are almost 100 percent efficient and can be recharged from completely dead in as little as one hour, depending on the charging technology and battery. This means they can deliver their full rated capacity. The built-in electronics automatically regulate the charging, and chargers designed specifically for lithium-ion batteries are highly recommended. Using a “general” charger could reduce the battery life, but this may not be noticeable by the user. It is important to understand the administrative functions that a particular battery management system controls, as not all battery circuitry is the same. Lithium-ion batteries require an onboard control circuit; therefore, the cost compared to lead-acid batteries is very high. However, such costs are defrayed when considering battery life, number of charges possible, and the energy output. (Thanks to Avanti Lalwani of Briter Products for assisting with lithium-ion specifics.)
6-Volt Or 12-Volt Batteries?
The key factor in this choice is current capacity. Two 6-volt batteries must be connected in series in order to achieve 12 volts, whereas two 12-volt batteries must be connected in parallel to maintain 12 volts. In the series configuration, the voltage doubles (6 volts + 6 volts = 12 volts), but the current stays the same. In the parallel scenario, the voltage stays the same, but the current doubles.
One major reason to use 6-volt batteries is to get more current capacity (measured in amp-hours), although that increase may be nominal. The question may arise: If current capacity doubles with two 12-volt batteries configured in parallel, why opt for 6-volt batteries wired in series? The answer: Because of denser plates in a 6-volt battery, the current capacity is more than double that of a single 12-volt battery. Therefore, by installing two 6-volt batteries in place of one 12-volt battery, the mathematical result is a higher current capacity.
*If money is not a concern, go with lithium-ion. You will have more battery per square foot, and much more current capacity, as these batteries are virtually 100 percent efficient. You also will be able to charge your battery bank very quickly, which is important when dry camping. And you will save significant weight, if this is important to you. Lithium-ion is the battery technology of the future, and I predict the price of these batteries may drop in the next few years. However, the high cost is the only downside, and that is largely offset by their high efficiency and long life. The question of which type of RV batteries to use remains a topic of debate in RV circles. RVers should collect information such as that provided in this article and consider their individual needs in order to make an educated decision.