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electrical:depth_of_discharge [2021/02/21 13:33]
frater_secessus [SoC by voltage]
electrical:depth_of_discharge [2023/08/17 21:36] (current)
frater_secessus [effect of DoD on lead battery life]
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 ===== Depth of discharge / State of Charge ===== ===== Depth of discharge / State of Charge =====
  
-{{ http://popupbackpacker.com/wp-content/uploads/2013/12/State-of-Charge-Chart-Trojan.jpg?200|}}//Depth-of-discharge (DoD or DOD)// refers to how low a deep cycle battery is taken between [[electrical:12v:charging|full charges]].  DoD is the inverse of //State of Charge (SoC)//.  Example:  a battery at 30% DoD is at 70% SoC.+//Depth-of-discharge// (DoD or DOD) refers to how low a deep cycle battery is taken between [[electrical:12v:charging|full charges]].  Specifically, what percentage of the rated capacity remains at a given point?   Example:  For solar powered systems the greatest DoD (and therefore lowest SoC) will be in early morning just before the panels start creating power again.
  
-For solar powered systems the greatest DoD (and therefore lowest SoC) will be in early morning just before the panels start creating power again.+DoD is the inverse of //State of Charge (SoC)//.  Example:  a battery at 30% DoD is at 70% SoC.
  
-DoD has a **significant impact on longevity of deep cycle batteries**.  For this reason [[electrical:inverter|Inverters]] and other high-load devices may have a [[electrical:12v:lvd|low voltage cutoff]]. +Note: This information is primarily relevant to lead-chemistry batteries.  Lithium batteries have [[#lithium_soc|different DoD capabilities and lifecycles]].
-===== effect of SoC on battery life =====+
  
-How deeply one regularly discharges lead-chemistry batteries will have a **direct effect on how long the battery bank will last**.((Banks are typically replaced when they have lost 20% of their capacity)) 
  
 +===== knowing when SoC is 100% (fully charged) =====
  
-The **most common discharge limit for deep cycle batteries is 50% DoD**.  This gives a good balance between usability and longevity.  The **lowest cost per Ah** occurs around 30% DoD although this requires buying, installing, and moving //dead lead// or unusable battery capacity.((20% DoD is the limit at which manufacturers rate their battery's cycles.))   
  
-Based on the following data on the Trojan T-105: +With **lead batteries** we know the battery is 100% when 
-  * lowest cost per Ah happens at 30DoD +  
-  * longest life happens at 20DoD +  * we are holding Absorption voltage; and 
-  * least battery weight happens at 80DoD +  * current acceptance has decreased to 0.02C, or about 2% of the rated capacity 
-so make your DoD decision based on what is most important to you.+ 
 +So for a 225Ah Trojan T-105 that might be when current acceptance drops to **4.5A at 14.8v**.  Some solar charge controllers have a setting for defining the final current acceptance ("trailing amps", "endAmps").  Usually humans observe system behavior and set an Absorption duration likely to terminate at about the correct time.((later typically better than earlier with lead)) 
 + 
 +Mythbusting although it is a common saying, a lead battery is not reliably 80% SoC when Absorption voltage is reached.  See [[opinion:frater_secessus:charging_faster|this article]] for why this is so.  
 + 
 + 
 +With **lithium batteries** humans might use use amp-counting with [[electrical:12v:battery_monitor|a battery monitor]] but most charge controllers don't talk to battery monitors.  So we can take one of two major approaches: 
 + 
 +  * at moderate charging rates like 0.2C((20A for a 100Ah LFP)) SoC will be ~100when voltage rises to 14.0v 
 +  * at moderate charging rates SoC will be ~100when voltage rises to 13.8v and we add perhaps 30 minutes of Absorption duration.  At that point current acceptance will fall off to somewhere between 0%-10%.   
 +  * at moderate charging rates and voltages between ≥13.4v and <13.8v SoC will be ~100after some amount of Absorption.  It could take a day at 13.4v and a few hours at 13.6v;  watch your battery monitor to see when acceptance actually falls off. 
 + 
 +==== soft and firm charging ==== 
 + 
 + 
 +Solar is typically a moderate (or "soft") charging source so the guidelines above are probably close enough to start from.  Alternator charging from [[electrical:12v:directcharginglfp|combiner]] or large [[electrical:12v:b2b|DC-DC]] may be high ("firm") enough for SoC estimates to be artificially high.   
 + 
 +So while we can say with confidence that a 100Ah Li battery charged at 20A to 14.0v will be ~100% SoC, the same battery charged to 14.0v at 80A might only be at 75% SoC.  And it **could get damagingly overcharged** if charged to 14.0v very gently at something like 5A.((the BMS cannot detect this scenario)) 
 + 
 +The amp counter will probably help here during charging although even it can be thrown off;  see the battery monitor article for more on this.  
 + 
 + 
 +===== estimating SoC while resting ===== 
 + 
 +{{ http://popupbackpacker.com/wp-content/uploads/2013/12/State-of-Charge-Chart-Trojan.jpg?200|}} 
 +A rested (no load), fully charged, unFloated lead battery will be 100% around 12.7v-12.8v; see specs for exact numbers.  //We can only reasonably assess SoC by voltage after a full charge.//  After charging is removed the lead battery will start to self-discharge (drain itself), which is why lead batteries require Float charging.  **A lead battery that has been fully charged and at Float voltage ever since is assumed to be 100%**. 
 + 
 +The famous chart to the right is used to estimate SoC of a rested battery after a full charge.   
 + 
 +A rested (no load), fully charged, unFloated lithium battery will be 100% around 13.5-13.6v.  Even with charging removed lithium self-discharge is very low.  The downside of this is that an overcharged Li battery can stay at unhealthy high levels for long periods before self-discharging to a safer range.  
 + 
 +As we will see below SoC-by-voltage will appear to be **artificially high during charging**((voltage rise)) and **artificially low during discharging**((voltage sag)).  With some "seat time" on your system you may learn how to interpolate with some degree of accuracy  
 + 
 + 
 + 
 + 
 + 
 +  
  
-| |  **T105 Ah**| |  **Cost**|  **weight per set**|  **Target Ah**| | | | 
-| |  225| |  $260.00|  124|  175| | | | 
-| | | | | | | | | | 
-| | | | | | | | | | 
-| | | | | | | | | | 
-|  **DoD**|  **State of Charge**|  **power per cycle**|  **Num. of cycles**|  **lifetime power in kAh((Ah *  1000))**|  **levelled cost / Kah**|  **life in years**|  **Sets needed for target Ah**|  **Weight**| 
-|  10|  90|  22.5| | | | | | | 
-|  20|  80|  45|  3000|  135|  $1.93|  8.2|  3.9|  482| 
-|  30|  70|  67.5|  2250|  151.875|  $1.71|  6.2|  2.6|  321| 
-|  40|  60|  90|  1450|  130.5|  $1.99|  4.0|  1.9|  241| 
-|  50|  50|  112.5|  1200|  135|  $1.93|  3.3|  1.6|  193| 
-|  60|  40|  135|  1050|  141.75|  $1.83|  2.9|  1.3|  161| 
-|  70|  30|  157.5|  900|  141.75|  $1.83|  2.5|  1.1|  138| 
-|  80|  20|  180|  800|  144|  $1.81|  2.2|  1.0|  121| 
-One can choose to [[electrical:severe battery use|run the batteries quite hard]] in emergency or temporary conditions with the understanding that it will likely "hurt" the batteries to some degree.  Consistently going past 50% DoD will greatly reduce the battery's usable cycles.  Some studies suggest discharging to 80% yields 1/10th the number of cycles available at 20%.   
  
  
-===== estimatating SoC ===== 
  
 ==== SoC by specific gravity ==== ==== SoC by specific gravity ====
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   * intermittent heavier loads that leave the system with measured >=12.2v when that load is removed   * intermittent heavier loads that leave the system with measured >=12.2v when that load is removed
  
-The more challenging task is judging when to kill the circuit based on voltage **under heavier loads**. Consider this chart:+===== estimating SoC while discharging ===== 
 + 
 +The more challenging task is judging SoC (including for LVD purposes) under heavier loads.   
 + 
 +Consider this chart for Trojan FLA batteries:
  
 {{ https://i.stack.imgur.com/bm93G.jpg}} {{ https://i.stack.imgur.com/bm93G.jpg}}
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 If the battery rebounds to the desired voltage then repeat to deeper discharge.  Stop when the battery no longer can rebound to the setpoint.  The LVD voltage is the lowest voltage the system can  drop to and still rebound to the desired setpoint when the load is removed.  If the battery rebounds to the desired voltage then repeat to deeper discharge.  Stop when the battery no longer can rebound to the setpoint.  The LVD voltage is the lowest voltage the system can  drop to and still rebound to the desired setpoint when the load is removed. 
  
 +
 +**Lithium batteries** also exhibit voltage sag under load but typically much less than AGM or especially FLA.  An [[electrical:12v:battery_monitor|amp-counting battery monitor]] is the most accurate tool here.  
 +
 +===== estimating SoC while charging =====
 +
 +Similar to voltage sag during discharge, batteries exhibit voltage //surge// or //rise// during charging.  As with discharge, the effect is very strong with FLA, medium with AGM, and lowest with Lithium.   
  
  
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 This section [[electrical:12v:psoc|has moved]]. This section [[electrical:12v:psoc|has moved]].
  
 +===== effect of DoD on lead battery life =====
 +
 +DoD has a **significant impact on longevity of lead deep cycle batteries**.((and, to a lesser degree, lithium batteries))  For this reason [[electrical:inverter|Inverters]] and other high-load devices may have a [[electrical:12v:lvd|low voltage cutoff]] to prevent going below a given SoC, typically 50%.  Since this is judged by voltage it is am imperfect science.
 +
 +
 +The **most common discharge limit for deep cycle batteries is 50% DoD**.  This gives a good balance between usability and longevity.  The **lowest cost per Ah** occurs around 30% DoD although this requires buying, installing, and moving //dead lead// or unusable battery capacity.  
 +
 +Based on the following data on the Trojan T-105:
 +  * lowest cost per Ah happens at 30% DoD
 +  * longest life happens at 20% DoD
 +  * least battery weight happens at 80% DoD
 +so make your DoD decision based on what is most important to you.
 +
 +| |  **T105 Ah**| |  **Cost**|  **weight per set**|  **Target Ah**| | | |
 +| |  225| |  $260.00|  124|  175| | | |
 +| | | | | | | | | |
 +| | | | | | | | | |
 +| | | | | | | | | |
 +|  **DoD**|  **State of Charge**|  **power per cycle**|  **Num. of cycles**|  **lifetime power in kAh((Ah *  1000))**|  **levelled cost / Kah**|  **life in years**|  **Sets needed for target Ah**|  **Weight**|
 +|  10|  90|  22.5| | | | | | |
 +|  20|  80|  45|  3000|  135|  $1.93|  8.2|  3.9|  482|
 +|  30|  70|  67.5|  2250|  151.875|  $1.71|  6.2|  2.6|  321|
 +|  40|  60|  90|  1450|  130.5|  $1.99|  4.0|  1.9|  241|
 +|  50|  50|  112.5|  1200|  135|  $1.93|  3.3|  1.6|  193|
 +|  60|  40|  135|  1050|  141.75|  $1.83|  2.9|  1.3|  161|
 +|  70|  30|  157.5|  900|  141.75|  $1.83|  2.5|  1.1|  138|
 +|  80|  20|  180|  800|  144|  $1.81|  2.2|  1.0|  121|
 +One can choose to [[electrical:severe battery use|run the batteries quite hard]] in emergency or temporary conditions with the understanding that it will likely "hurt" the batteries to some degree.  Consistently going past 50% DoD will greatly reduce the battery's usable cycles.  Some studies suggest discharging to 80% yields 1/10th the number of cycles available at 20%.  
 +
 +
 +===== lithium SoC =====
 +
 +Lithium chemistries have very flat voltage curves, making it  notoriously difficult to gauge SoC by voltage.  In this case [[electrical:12v:battery_monitor|a shunted battery monitor]] is used to count amps as they go in/out.  If the Li battery has connectivity you may be able to read SoC from the internal BMS. 
electrical/depth_of_discharge.1613932434.txt.gz · Last modified: 2021/02/21 13:33 by frater_secessus