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I've been running this new boat with a F200 (4 cylinders, 2.785 liter, 4 stroke) this season and now I'm starting with a major upgrade to the electrical system. Quite much of my understanding of the issues comes from Nigel Calder's excellent book (4th ed, 2015).
The boat has started out with a dual battery system with the regular old fashioned open wet-cell lead acid cranking batteries, 2 x 100 Ah. I might stay up to 3 nights in one place without access to external electricity and few possibilities of charging, so capacity and charging become central issues. I understand Yamaha engines generally come with automotive style alternators/regulators, though newer ones have somehow "smart" versions. The base model of operation is constant voltage charging which will top off the batteries only very, very slowly while the boat is underway.
The idea is to replace/extend the house bank with a more capable AGM or lithium battery. Especially with the lithium option, I could connect a battery-to-battery charger to the circuit powered by the alternator and separately charge the house battery (naturally isolated from loads during charging). This would have the benefit of driving the alternator with a much higher output current and thus charging the battery system much faster than currently while the engine is running. The max alternator output is 50A - the charger would provide a charging current of 30A (some additional efficiency losses would need to be factored in). Sterling makes excellent chargers and I would probably use this one: https://www.svb24.com/en/sterling-pr...y-charger.html
Some issues, questions and notes:
1) Is this a good idea with Yamaha outboards? From some comments on this forum I understood that the alternators can be run for long periods at high output, but Calder notes that many alternators are designed to start with a high current which quickly becomes lower, thus a lower load and a lower amount of heat is generated over time. I understood overheating can be an issue with Yamaha alternators?
2) Sterling provides for temperature sensing, which could perhaps be installed at the regulator/alternator? There is a large duct going from the technical insides of the boat through the rear wall of a some kind of a cocpit to the engine - the wires could perhaps be routed via this duct like so many that already go to the engine, not sure if this would be a pain for the (professional?) installer?
3) Will it mess up the function of the Yamaha regulator. The charger as I understand would be no different from the other loads such as boat electronics, and is not very sensitive to input voltage, so the regulator can provide whatever voltage it feels happy with - only the current consumed would be quite high.
4) I might occasionally run the engine three hours in a row, possibly even longer. It is not typical to run for very long periods at high RPM, time to time it will drop below 2000 RPM, and sometimes will stay there for a while. Would sufficient output at low RPM be an issue, sometimes I'll run the engine at idle RPM (or off gear). The Sterling charger provides some handy functions such as automatically switching off when the input voltage is low, or the charge current can be set to 1/2 normal in case there are issues. Or the charger could just be disconnected in unusually problematic cases.
5) One post claimed that the rated alternator output is not provided to the electrical system as such, but a small chunk (10A?) goes actually back to the engine itself just to keep it running. (Makes sense, there's several electrical and electronic components inside modern engines.)
AGM and lithium (LiFePo) are attractive technologies for my needs because they tolerate deep discharge and can be charged rapidly, especially for lithium. LiFe batteries are also very light, which provides modest performance increases, means they are light to move around but above all help with fuel savings - it's a planing boat. Main disadvantages are the high cost and a short track record on the marine market. Technically the lithium batteries could pay themselves back in 20 years with just the fuel savings resulting from a lower weight.
The boat has started out with a dual battery system with the regular old fashioned open wet-cell lead acid cranking batteries, 2 x 100 Ah. I might stay up to 3 nights in one place without access to external electricity and few possibilities of charging, so capacity and charging become central issues. I understand Yamaha engines generally come with automotive style alternators/regulators, though newer ones have somehow "smart" versions. The base model of operation is constant voltage charging which will top off the batteries only very, very slowly while the boat is underway.
The idea is to replace/extend the house bank with a more capable AGM or lithium battery. Especially with the lithium option, I could connect a battery-to-battery charger to the circuit powered by the alternator and separately charge the house battery (naturally isolated from loads during charging). This would have the benefit of driving the alternator with a much higher output current and thus charging the battery system much faster than currently while the engine is running. The max alternator output is 50A - the charger would provide a charging current of 30A (some additional efficiency losses would need to be factored in). Sterling makes excellent chargers and I would probably use this one: https://www.svb24.com/en/sterling-pr...y-charger.html
Some issues, questions and notes:
1) Is this a good idea with Yamaha outboards? From some comments on this forum I understood that the alternators can be run for long periods at high output, but Calder notes that many alternators are designed to start with a high current which quickly becomes lower, thus a lower load and a lower amount of heat is generated over time. I understood overheating can be an issue with Yamaha alternators?
2) Sterling provides for temperature sensing, which could perhaps be installed at the regulator/alternator? There is a large duct going from the technical insides of the boat through the rear wall of a some kind of a cocpit to the engine - the wires could perhaps be routed via this duct like so many that already go to the engine, not sure if this would be a pain for the (professional?) installer?
3) Will it mess up the function of the Yamaha regulator. The charger as I understand would be no different from the other loads such as boat electronics, and is not very sensitive to input voltage, so the regulator can provide whatever voltage it feels happy with - only the current consumed would be quite high.
4) I might occasionally run the engine three hours in a row, possibly even longer. It is not typical to run for very long periods at high RPM, time to time it will drop below 2000 RPM, and sometimes will stay there for a while. Would sufficient output at low RPM be an issue, sometimes I'll run the engine at idle RPM (or off gear). The Sterling charger provides some handy functions such as automatically switching off when the input voltage is low, or the charge current can be set to 1/2 normal in case there are issues. Or the charger could just be disconnected in unusually problematic cases.
5) One post claimed that the rated alternator output is not provided to the electrical system as such, but a small chunk (10A?) goes actually back to the engine itself just to keep it running. (Makes sense, there's several electrical and electronic components inside modern engines.)
AGM and lithium (LiFePo) are attractive technologies for my needs because they tolerate deep discharge and can be charged rapidly, especially for lithium. LiFe batteries are also very light, which provides modest performance increases, means they are light to move around but above all help with fuel savings - it's a planing boat. Main disadvantages are the high cost and a short track record on the marine market. Technically the lithium batteries could pay themselves back in 20 years with just the fuel savings resulting from a lower weight.
Yes there were a few caveats like that but you get the idea, hopefully. Wet cell cranking batteries seem to last about 6 years in my use; recall lithium was given a 10 - 15 years quote somewhere, should maybe recheck and calibrate the figures before I make decisions. Then again, lithium batteries of today are much more capable than they were just 10 years ago.
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