Lead acid batteries are made from a mixture of lead plates and sulfuric acid. Lithium ion batteries on the other hand are a much newer invention, and have only been around in a commercially viable form since the 1980’s. Lithium technology has become well proven and understood for its long shelf life and is widely used for several appliances and products.
1. Superior “Useable” Capacity
Unlike with lead acid batteries, it is considered practical to regularly use 90% or more of the rated capacity of a lithium battery bank, and occasionally more. Consider a 100 amp hour battery – if it was lead acid you would be wise to use just 30 to 50 amp hours of juice, but with lithium you could tap into 90 amp hours or even 100Ah (100% DoD).
Lithium-Ion usable capacity
2. Extended Cycle Life
Laboratory results indicate that you could expect to see 2000 to 5000 cycles out of a well cared for Lithium Ion Phosphate battery bank. Both C-Rate and Depth of Discharge (DoD) affect expected lifespan. Some recent measurement shows that a LFP battery will still deliver more than 80% of it’s capacity after 2000 cycles at 100% DoD or even 5000 cycles at 65% DoD. All these tests are done at 1C-Rate Cycles.
These cycle life results are much more better than NMC or NCA chemistries, massively used in electric vehicle industry. In contrast, even the best deep cycle lead acid batteries are typically only good for 500-1000 cycles. Picture below shows the expected number of cycles for Lithium-Ion-Phosphate batteries at different DoD at 1C-rate.
Lithium Ion Phosphate cycle life test
3. Peukert’s Losses & Voltage Sag Virtually Non Existent
The discharge curve of lithium batteries (especially relative to lead acid) is essentially flat – meaning that a 20% charged battery will be providing nearly the same output voltage as an 80% charged battery. This prevents any issues caused by the “voltage sag” common to lead acid as they discharge, but does mean that any battery monitor or generator auto-start dependent upon voltage levels will likely not work well at all when monitoring a lithium bank.
Lithium-Ion discharge curves
On the flip side, once lithium batteries are fully discharged, their voltage takes a nose-dive quickly – which is the BMS role to protect the batteries to absolutely never let this happen. Completely discharging a lithium ion bank, even once, can render your entire pack permanently dead.
Another huge advantage of lithium batteries is that Peukert’s losses are essentially non-existant. This means that Lithium-Ion batteries can deliver their full rated capacity, even at high currents. Whereas lead acid can see as much as a 40% loss of capacity at high loads. In practice, this means that Lithium-Ion battery banks are very well suited to powering high current loads like an air conditioner, a microwave or an induction cooktop.
Lithium-Ion-Phosphate Discharge curves at different C rates
4. Size & Weight Advantages
To highlight the unique characteristics in terms of weight and size of the lithium-ion batteries, let’s take concrete example : lead acid vs Lithium battery.
5. Fast & Efficient Charging
Lithium-ion batteries can be “fast” charged to 100% of capacity. Unlike with lead acid, there is no need for an absorption phase to get the final 20% stored. And, if your charger is powerful enough, lithium batteries can also be charged insanely fast. If you can provide enough charging amps – you can actually fully charge a lithium ion battery just 30 minutes.
But even if you don’t manage to fully top off to 100%, no worries – unlike with lead acid, a failure to regularly fully charge Lithium-Ion batteries does not damage the batteries.
This give you lots of flexibility to tap into energy sources whenever you can get them without worrying about needing to do a full charge regularly. Several partly cloudy days with your solar system? No problem that you can’t top off before the sun goes down, as long as you’re keeping on top of your needs. With lithium, you can charge up what you can and not fret about leaving your battery bank perpetually undercharged.
6. Very Little Wasted Energy
Lead acid batteries are less efficient at storing power than lithium ion batteries. Lithium batteries charge at nearly 100% efficiency, compared to the 85% efficiency of most lead acid batteries.
This can be especially important when charging via solar, when you are trying to squeeze as much efficiency out of every amp as possible before the sun goes down or gets covered up by clouds. Theoretically, with lithium nearly every drop of sun you’re able to collect goes into your batteries. With limited roof & storage space for panels, this become very important in optimizing every square inch of wattage you’re able to mount.
7. Climate Resistance
Lead acid batteries and lithium lose their capacity in cold environments. As you can see in the diagram below, Lithium-ion batteries are much more efficient at low temperatures. Moreover, the discharge rate affects the performance of lead acid batteries. At -20°C, a Lithium battery that delivers a 1C current (one times its capacity), can deliver more than 80% of its energy when the AGM battery will deliver 30% of its capacity. For harsh environments (hot and cold), Lithium-Ion is the technological choice.
Capacity vs temperature
8. Fewer Placement Issues
Lithium-ion batteries do not need to be stored upright, or in a vented battery compartment. They can also fairly easily be assembled into odd shapes – an advantage if you are trying to squeeze as much power as possible into a small compartment. This is especially useful if you have an existing battery bay that is limited in size, but you want or need more capacity than lead acid is currently able to provide.
9. Zero maintenance requirements
Lithium-Ion batteries are fairly maintenance free. A “balancing” process to make sure all the cells in a battery bank are equally charged is automatically achieved by the BMS (Battery Management System). Just charge you battery and you are good to go.