float @ 90% SOC

Photowhit said:

mcgivor said:

Photowhit said:

mcgivor said:

Seems strange to me to limit or skip absorbtion, my manual, not Midnight, states that absorbtion is the most important stage of charging. Is there not a default setting, usually the engineers who developed the controller have a pretty good idea of what a battery needs.

They don't know what type or capacity battery you have.

But they should have settings for various types, FLA, L16, AGM etc. Would this not be an accurate assumption?

There will be basic setting, AGM, FLA, ...


But think of all the different types of setups, You can have a 4K watt array feeding a lead acid battery! A weekend setup with a huge bank say 1200ah forklift battery, providing just a 5% charge rate, or a 400ah bank in a cloudy region. A finishing rate of 30 amps or 2-3% of a 1200 ah battery is charging rate for a small battery bank. Best to input a finishing rate perhaps more than a timed charging, and perhaps they might consider that at some point, but I think that varies by type as well. I mostly have had FLA.

Vic said:

dapago,

Personally,  would set the Absorb (called 'Bulk'  by Trojan)   voltage,   as specified in the Data Sheet in the following Link  --  59.28 V,  59.3 should be fine:
http://www.trojanbattery.com/pdf/datasheets/T105RE_TrojanRE_Data_Sheets.pdf

Float is noted as 54.0 V,  and EQ V is 64.8 V.

Target SG for full-charge is 1.277.

I,  too,  use Skip Days  --  Skip three,  and charge on the fourth day.
BUT.   dapago probably needs to find settings that will bring the battery bank to full-charge,  before Skipping Days.

Be certain to mount the BTS on one battery in the center of the battery bank.

The  Temperature Compensation value is -- 5 mV/Cell/C.   Would suggest setting Temp Comp EQ = YES.

As suggested elsewhere,  would set the Charge voltages to those recommended by Trojan,  and watch the SGs to see how they respond.  If still not reaching 1.277 SGs,  then try increasing the Absorb time by about 30 minutes,  for a start:
http://kb1uas.com/mnsforum/index.php?topic=3560.0

The Classic Ending Amps function works great,  when using the WBjr with a 50 mV 500 A Shunt.   CC EA (without a WBjr)  can work well,   especially if there are no heavy loads that are present near the time when Absorb should be ending.   Heavy loads that cycle every few minutes should not be an issue when using CC EA,  as long as the heavy load is off for about five minutes or so.  Used CC EA for about 5 - 6 years without any problems.

All FWIW,   Vic

Say for example you had a battery which has no loads and is fully charged at days end, overnight the self discharge is almost negligible, the next day sun up battery is at 99.9%  charged, the controller sees the voltage and instead of doing a bulk charge goes immediately into absorbtion, after the time out of absorption, it switches into float.

Next night the battery is discharged to 80% SOC, following morning the controller reads the voltage and goes into bulk until the absorption setpoint is met, absorbtion takes place and times out, then float. This is using a standard algorithm without user input, would this not be a good starting point, to establish a base line from which to adjust setpoints and timed functions to suit particular needs of a system, if needed, wether it be a daily or weekend  use, or specific battery requiments. Sometimes too many interventions can lead to problems and these can sneak up undetected and result in premature battery failure.
In the case of @dapago, it would seem his array is a little too large for the battery, 2480W for 225Ah, so if anything the bulk amperage may be on the high side, but once it goes into absorbtion, the current should drop as the level of charge increases. So if it is possible to limit the bulk charge current would this not be the prudent thing to do? The absorption stage would taper the current down to avoid gassing and terminate when the time has expired, then go into float, assuming there are no large loads which may prompt the controller into going back into bulk. 

There seems to be different  uses for the term bulk/absorbtion as @Vic stated so I copied the information from a Morningstar manual which are the terminologys as I understand them. So as @Estragon mentioned using absorbtion to mix the electrolyte, is this bulk being referred to as absorbtion, as bulk is more likely to do just that.

The TriStar MPPT 150V has a 4-stage battery charging algorithm for rapid, efficient, and safe 

battery charging.

Bulk Charge Stage

In Bulk charging stage, the battery is not at 100% state of charge and battery voltage has not yet 

charged to the Absorption voltage set-point. The controller will deliver 100% of available solar 

power to recharge the battery.

Absorption Stage

When the battery has recharged to the Absorption voltage set-point, constant-voltage regulation 

is used to maintain battery voltage at the Absorption set-point. This prevents heating and exces-

sive battery gasing. The battery is allowed to come to full state of charge at the Absorption volt-

age set-point. The green SOC LED will blink once per second during Absorption charging.

The battery must remain in the Absorption charging stage for a cumulative 120 - 150 minutes, 

depending on battery type, before transition to the Float stage will occur. However, Absorption 

time will be extended by 30 minutes if the battery discharges below 12.5 Volts (25 Volts @24 V, 

50 Volts @48 V) the previous night.

The Absorption set-point is temperature compensated if the RTS is connected; otherwise, 

voltages set-points are based on the reference of 25ºC.

.

Float Stage

After the battery is fully charged in the Absorption stage, the TriStar MPPT 150V reduces the 

battery voltage to the Float voltage set-point. When the battery is fully recharged, there can be 

no more chemical reactions and all the charging current is turned into heat and gasing. The float 

stage provides a very low rate of maintenance charging while reducing the heating and gasing of 

a fully charged battery. The purpose of float is to protect the battery from long-term overcharge. 

The green SOC LED will blink once every two (2) seconds during Float charging.

Once in Float stage, loads can continue to draw power from the battery. In the event that the 

system load(s) exceed the solar charge current, the controller will no longer be able to maintain 

the battery at the Float set-point. Should the battery voltage remain below the Float set-point for 

a cumulative 60 minute period, the controller will exit Float stage and return to Bulk charging.

The Float set-point is temperature compensated if the RTS is connected; otherwise, voltages 

set-points are based on the reference of 25ºC.

Equalize Stage