For the .4C test the timer was reset to 12:00 and an image was snapped using an intervalometer at 2 minute increments. At 2 minutes the voltage at .4C had already risen to 13.6V.

If you read the highlighted part of the Lifeline Battery Technical Manual you will see that Lifeline correctly understands the difference between BULK and ABSORPTION charging. Many companies, including Balmar and many others, do not correctly understand using the word "bulk" correctly. When a company tells you that "bulk" is a voltage limited stage of charging this is PURE MARKETING BOVINE DUNG. Simply put bulk=constant current charging not constant voltage.

BULK - Bulk Charging is the constant current stage of charging where the charge source is limited only by what it can deliver in current. Bulk charging is not a voltage limited stage of charging despite many companies bastardizing the term bulk for apparent marketing purposes.

ABSORPTION - Absorption, float and equalization are all examples of constant voltage charging stages. Absorption or constant voltage is where the charge source holds voltage steady, hence the term "constant voltage". Once voltage is held steady, or it becomes voltage limited, current begins to decline and the charge efficiency worsens. Float charging is a further reduction in the constant voltage limit and an equalization voltage would be a further increase in the constant voltage limit of charging.

The charging devices we use on boats are all considered CC > CV charge sources, or constant current then to constant voltage. Simple stuff really. Please understand that BULK is not a voltage limited stage of charging, despite the marketing guru's vastly missing the mark on this one...

Kudo's to the guys at Lifeline Battery for properly understanding the difference between BULK and ABSORPTION. Shame on companies like Balmar for grossly misleading the consumer.. Words mean certain things and when we blur the definitions to sell $hit, it CONFUSES PEOPLE. (grin)

Let's take a look at a Balmar regulator and use their terminology then a more accurate terminology:

What it should read: Bulk/CC, Pre-Absorption/CV, Absorption/CV, Float/CV

Please remember that bulk is not a voltage limited stage of charging it is constant current.

By 1 hour in our 42A / .4C charge current has already declined to 19.5A..

Here we are at 3 hours and current is now down to 2.8A.. That last few % takes the longest!

Here we are finally at 100% SOC. 100% SOC was deemed as 0.525A flowing into the battery at 14.4V per the Lifeline Battery Technical Manual.

At a .4C charge rate it took this fairly healthy, though not perfect, group 31 battery 5:30 to reach 100% SOC from 49.3% SOC.

At 1 hour the battery voltage has only risen to 13.8V at a .2C charge rate. The .4C charge rate had attained 14.4V at 19 minutes.

If this was your alternator it had better be robust enough to deliver its full output for at least 1 hour straight. In this case, as you see next, 1:16 minutes before it starts to catch a break. A charge rate of .2C on a 450Ah bank, a pretty typical bank on a coastal cruiser these days, is an alternator that can deliver 90A continuously even when hot.

At 2 hours the current is down to 11A..

At 4 hours the battery is accepting just 1.6A..

Here we are at 100% SOC at the .2C charge rate and it took 5:42 minutes.

Yes it took longer to attain 100% SOC (per Lifeline battery tech manual) but that time was only approx 12 minutes different with double the charge rate. Both charge rates took 5.5+ hours and I have repeated this test with AGM batteries is worse shape that exceeded 7 hours to attain 100% SOC likely due to sulfation.

IMPORTANT: Please understand that you will never likely charge this fast with a typical smart charger. Take for example the .4C charge rate. At 19 minutes it hit absorption voltage. Many so called "smart chargers" begin a timer, I call it an egg timer, once absorption voltage has been attained. If that clock started at 19 minutes, and was 2 hours long, the charger would have dropped to a float voltage of 13.4V at 2:19 minutes! OUCH!!!! Considering it took 5:11 minutes of absorption charging at the .4C charge rate your batteries would likely end up under absorbed, under charged and would not last very long. Once we reduce voltage, eg: dropping to float prematurely, we dramatically EXTEND charging times. In my shop I use adjustable power supplies to avoid dumb smart chargers. With a power supply I can control when the battery changes from absorption to float and not rely on an egg timer.

Is too much current bad for an AGM Battery?

For AGM batteries generally the more current the better. It helps with overall longevity to charge at high rates. Higher charge rates in AGM batteries actually yields longer life not shorter life.

Dave V. the lead engineer at Lifeline battery published a study supporting higher charge rates being good for AGM's.. Odyssey battery, thin plate pure lead AGM batteries, wants to see a minimum of .4C and Lifeline a minimum of .2C as recommended charge current.

This is from the conclusion section of Dave V's study:

"In order to achieve the maximum cycle life from sealed lead acid batteries, (AGM) not only should the DOD be kept as low as possible, but the charge current limit should be as high as possible."

The study then goes on to suggest that a balance needs to be met between equipment and optimal cycle life. Today Dave suggests a minimum charge current of .2C for Lifeline AGM's.

It is a pretty rare boat that can muster a .4C charge rate but some do. On a 450Ah bank that would be an alternator or larger inverter chargers that could sustain 180A when hot.

You as a boat owner will have to decide what it's worth in terms of equipment costs to charge at your AGM's at high charge rates. The eternal question of "Do AGM's charge faster with high charge rates applied?" seems to still be open for debate. This battery only saw an approx 12 minute difference in a 5.5hour charge period but yes it did charge "faster" at .4C than it did at .2C.

In this second part of the testing I am replicating a few typical scenarios for recharging on a cruising boat. No one wants to run the engine or generator for very long so I wanted to illustrate what kind of energy can be stored in the AGM battery at a 2 hour time interval at a .2C charge rate.

This test started with a discharge from 100% SOC to 50% SOC with the battery delivering 47.85Ah at a 5.25A constant current load. The battery was then recharged for exactly 2 hours at .2C and then immediately discharged back to 50% SOC and the stored energy for that cycle was measured.

The charge rate for this test was 21A and the timer set for 2 hours. If the battery could stay in bulk for two hours our maximum potential energy into the battery would be 42A. Because the battery hit absorption voltage, before hitting the 2 hour mark, we simply can not get 42Ah of energy into the battery...

In this image the charge source is about to turn off when it hits the 2 hour mark. Net accepted current at 14.4V @ 1:58 is down to 11.6A.

After charging the battery from 50% SOC for two hours at 21A we were able to remove 35.28Ah's and bring the battery back down to 50% SOC.

Let's do the math:

Baseline Ah Capacity = 95.69Ah

Discharge to 50% = 47.84Ah (left in the battery after discharge)

2 Hour charge then discharged and counted Ah's delivered back to 50% SOC = 35.28Ah

47.84Ah + 35.28Ah = 83.12Ah of stored energy

83.12 is 86.9% of the baseline Ah capacity of 95.69Ah's

BOTTOM LINE: The battery achieved approx 87% SOC in two hours at a .2C charge rate

This test was a .2C charge for one hour and then discharged back to 50% SOC, after the 1 hour charge. The stored energy removed was 20.46Ah from a max charge rate of 21A.

CHARGE EFFICIENCY: As I have mentioned before bulk charging, where the charge source provides its full current before the battery reaches the limiting voltage is nearly 100% efficient. Here we have a 1 hour recharge at a charge rate of 21A where the battery was able to store 20.46Ah of that 21A. A 21A charge for 60 minutes is 21Ah's of supplied energy. This means 97.4% of the energy supplied by the charger, or the 21A for exactly 1 hour, was removable as stored energy when we discharged back to 50% SOC. On this 1 hour .2C recharge the battery never attained the absorption voltage of 14.4V and was still in bulk when the charger turned off at the one hour mark.

SCALE IT UP: If we scale this test up, and it should scale well, a .2C charge rate on a 450Ah fairly typical cruising boats house bank would be a continuous 90A for 1 hour before your batteries even hit the absorption voltage set point. Yes, 90A continuously for 1 HOUR!! This is a metric $hit ton of work on a typical 80A - 120A alternator. This is why many a boater has burned up their alternators charging AGM batteries!

MYTH BUSTING: If you believe a battery monitor that counts Ah's, and supplies a fixed charge efficiency number to the returned Ah's (most all of them), can track your batteries accurately when you don't recharge to 100% SOC with each cycle, this myth & lore is blown out of the water right here. In bulk this battery had returned energy efficiency of 97.4% yet the last 4% of returned energy, to 100% SOC, takes 3.5 hours. There is a major difference in charge efficiency throughout the SOC curve. Charge efficiency is not linear throughout the SOC curve, but most all battery monitors are linear in their application of charge efficiency. They simply apply a negative count factor for charge efficiency as the Ah's are returned. For example if we return 10Ah's with a 90% charge efficiency setting the battery monitor will only show that as 9Ah's returned. If we were to stop charging in bulk we really do have closer to 10Ah's returned. Do this a few times........ Ouch! When you cycle more than a few times in the 50% to 90% SOC range there is no way for a typical Ah counter/battery monitor to accurately track your charge efficiency. For more info on this see my article on "Programming a Battery Monitor".

Let's do the math:

Baseline Ah Capacity = 95.69Ah

Discharge to 50% = 47.44Ah (left in the battery after discharge)

1 Hour .2C charge then discharged and counted Ah's delivered back to 50% SOC = 20.46Ah

47.44Ah + 20.46Ah = 67.90Ah of stored energy

67.90Ah is approx 71% of the baseline Ah capacity of 95.69Ah's

BOTTOM LINE: The battery achieved approx 71% SOC in one hour at a .2C charge rate.

PERSPECTIVE: It is pretty clear that a 1 hour charge at .2C is an inadequate charge rate for AGM batteries that are routinely discharged to 50% SOC, unless you really like hearing your motor or generator run.

NOTE: Lifeline Battery recommends a .2C charge rate as the bare minimum for these expensive AGM batteries. Odyssey TPPL AGM batteries are recommended to be charged at a minimum of .4C.

Here is another way to look at the charge process. This was a *Lifeline GPL-31XT battery (125Ah rated that was charged at .15C or about 15% of its rated Ah capacity. *NOTE: This was not the battery being tested in this article, and it was used. This image is just for just for illustrative purposes..

BULK: If we start at the top left of the chart we can see that the current held rock steady at 18.75A for *1:42 minutes. This current, 18.75A is .15C or a 15% charging current of a 125Ah battery.

*NOTE: 1:42 minutes of bulk charging (your alternator running at full bore) is more than enough to damage an alternator not otherwise protected for temperature or current limited to protect it. A charge rate of .15C would be an 80-90A alternator on a 400Ah bank, when accounting for the "hot" output, and not all that uncommon. I see lots of burned up alternators when they are under sized for the task.

VOLTAGE RISE: If we look at the left side of the chart we can see the voltage climbing to the absorption set point of 14.4V. It took 1:42 minutes at 18.75A for the battery voltage to attain 14.4V.

1/3 From Left: This is the point where the charge current and voltage flip-flop. Voltage stops climbing and is held steady, and current changes from being steady/constant to declining. Once the BULK/constant current charge has driven the battery voltage to the absorption voltage limit, the voltage is now limited or held steady and the charging current begins to decline.

CHARGE TIME: As current declines, out towards the lower right of the chart, the time it takes to get that last few % in takes significant time. At .15C this slightly used AGM took a bit over 6 hours to reach 100% SOC. I have had sulfated AGM batteries take 7+ hours even at a higher .2C. The health of your AGM battery can impact your time to full.

1- 50% SOC to 100% SOC at .2C = 5:42 - Exited Bulk Charge at 1:16:00
2- 50% SOC to 100% SOC at .4C = 5:30:00 - Exited Bulk Charge at 19 Minutes
3- 50% SOC Charged at .2C For Exactly 1 Hour = 71% SOC - Never Exited Bulk
4- 50% SOC Charged at .4C For Exactly 1 Hour = 85% SOC - Exited Bulk Charge at 19 Minutes
5- 50% SOC Charged at .2C For Exactly 2 Hours = 87% SOC - Exited Bulk Charge at 1:16:00
6- 50% SOC Charged at .4C For Exactly 2 Hours = 96% SOC - Exited Bulk Charge at 19 Minutes

DISCLAIMER: All batteries will test & perform differently based on age, type, chemistry and state of health. This battery and test are only really representative of this battery and test but should give some decent guidance as to what one may expect from a slightly used AGM battery. I purposely did not test a brand new AGM because that is not at all representative of what we as boaters have in use on-board our vessels for more than a short period of time. New batteries will perform differently but our batteries on boats rarely stay new for very long.

Good luck & happy boating!!