DRAFT ====== sizing a house battery bank ====== ===== assumptions ===== * Everything in this article assumes you have already assessed your [[electrical:12v:dailypowerrequirements|daily power requirements]] (DPR). The article will stipulate a DPR of 1,000Wh (1kWh). This 1,000Wh will be the base of all our calculations below. * We will think in terms of 12v systems and 100Ah batteries. * We will assume lithium = the common LiFePO4 (12.8v) ===== factors ===== ==== battery bank chemistry ==== === usable capacity === * lead-chemistry batteries (FLA, AGM, GEL) are typically [[electrical:nominal|nominal]] 12v and discharged to 50% [[electrical:depth_of_discharge|Depth of Discharge]]. A 100Ah lead battery holds ~1,200Wh (100Ah x 12v), and one discharged to 50% holds 600Wh (1,200Wh x 0.5). It would take **166Ah of lead** battery to give us 1,000Wh usable. (1,000Wh / 600Wh = 1.66 100Ah batteries) * lithium batteries are typically nominal 12.8v and discharged to 80% DoD. A 100Ah LFP battery holds 1,280Wh, of which 1,024Wh are usable (1,280Wh x 0.8). It would take **98Ah of LFP** to give us 1,000Wh usable. (1,000Wh / 1,024Wh = ~0.98 100Ah batteries) == throughput == 'Dwellers contemplating large currents relative to capacity ("[[electrical:12v:battery_capacity|C rates]]") might have to oversize the bank to get sufficient throughput, and/or choose a chemistry with lower resistance. FLA are famously stingy with current, AGM good, and Lithium excellent. ==== load timing ==== The simplest model assumes the bank will be charged then all the [[electrical:12v:loads|loads]] will be run from the bank. In real life **sometimes loads are running while the system is making power**. * running a 400w when solar is producing 200w means a net load of 200w. * running a 100w while alternator charging is producing may mean a net load of 0w (a freebie, in terms of battery capacity) You may want to add a section to your DPR spreadsheet to account for load use while solar is present, etc. In extreme cases only a very small bank may be required if most loads are effectively run [[electrical:solar:offthepanel|off the panel]]. ==== charging ==== === charging stability and predictability === Charging can be very predictable or highly unpredictable. More predictable charging allows smaller battery banks, and less predictable charging may require bigger banks unaffected by [[electrical:12v:psoc|PSoC]] to cover the variability. * [[electrical:shore_power|shore power]] (plugged in somewhere) is extremely predictable. It will make 15.20A, 30A, whatever, as long as you are plugged in. * same for charging with [[electrical:generator|generator]]; as long as it's running you have predictable charging * alternator charging with DC-DC is relatively predictable; it will charge at the DC-DC's rated output until the bank hit's absorption * alternator charging with combiner is less predictable; it will tend to start off with higher current at lower SoC and taper off as the bank reaches the alternator voltage * solar charging is highly unpredictable, being greatly affected by weather and [[electrical:solar:output|other factors]]. Rigs with solar-only charging may have to plan for days of minimal harvest, or have the flexibility to reduce consumption when solar harvest is compromised. === minimum current requirements === Lead chemistries typically have minimum charging current requirements to stay healthy * FLA 0.10C (10A for every 100Ah of capacity) * AGM 0.20C (20A for every 100Ah of capacity) If we cannot meet minimums the bank should be downsized (or [[electrical:12v:alt_and_solar|charging increased]]). Note: Lithium has no minimum charging current === maximum charging limits === Battery chemistries typically have maximum charging currents that can stress charging systems (particularly alternators via combiners): * FLA 0.20C (20A for every 100Ah of capacity) * AGM 0.33C (33A for every 100Ah of capacity) * LFP 1.0C (100A for every 100Ah of capacity) If the alternator can only safely provide 50A of charging to the house bank this would limit us to a 166Ah AGM bank (166Ah x 0.33 = 50A). If the alternator has excess capacity then a larger bank can accept more current. This doesn't mean the bank would get full any faster((it's larger, after all)) but you will gather more Ah/Wh on any given run.