There are some simple physics equations that show that the magnetic fields and windings generate heat. I think this is what JFM is saying. Forget about the precision engineering in the motor bearings and gearbox, these will produce some small elements, but generally the oil film in shear should reduce losses to near zero. It is actually the conversion of electrical energy into kinetic that will create the heat losses, if I remember my physics.
MapisM i agree to divide this into the two separate points
Rafiki, no that's absolutely not what I'm saying and that statmeent is not correct. What I'm saying is that the work done (kinetic energy) by a fin stab mecahnism is diddly squat. The function of the actuator mechanism is to create huge force (torque) but not to move very far. Every electric motor has an element of the electromagnetic crane in it but in my quadcoptor motors it is about 1% and in the fin stabiliser motor it is more like 99%. Now, when you are creating a force as opposed to doing work, then your motor winding becomes a resistor like an electric fire, and although all you actually WANT is electric current, man unfortunately has no ways at 20 degrees C to make current without heat, because all the materials we have discovered have electrical resistance at normal temps (as distinct from zero kelvins when we have superconductors). Thus in this scenario with the fin moving +/- 5 degrees or whatever and almost no work being done and almost no kinetic energy being created (literally a handful of Joules is all the kinetic energy you're making), almost all the energy consumed goes to overcoming electrical resistance in the winding, ie making heat not doing work.
Mike, you are missing the point. The data you quote is for motors that are doing work. If you stall a motor or near stall it, ie you put in a position of creating a large force but moving it almost no distance, which is what a fin stab motor does in the "hold the fin at an angle while boat does 20kts" scenario, you are deliberately causing the motor not to do work. Then it isn't 15% of the electricity that makes heat but 95%
. I think it is the magnetic flux in the windings creating the heat, but it is so long since I did this sort of physics that these things are lost in the mists of time.......
J, this is EXACTLY the point which doesn't hold water against my "common sense" check - naive as it might be.
Nope, sorry. My own common sense tells me that the fin surface is the only (well, almost) key factor for stabilizing a CRUISING hull.
B, you must jump in the water again I'm afraid.
Erk , I cannot think of any better way to explain this than I already have done. Your common sense meter is out of calibration here. There is no work done by a magnetic field unless it moves something, and in the crane scenario nothing moves. Imagine that you replaced the crane magnet with a traditional steel hook. The hook holds a tonne of steel, yet needs no power supply. Hence, the holding of one tonne of metal suspended above the ground needs no power and no source of energy. It consumes zero energy. It only needs a force, to resist gravity, but you can have a force with no energy supply - that is what a hook does, or a nut and a bolt, or a million other things you can think of like Velcro. Now, an electromagnet needs current to create a force. It does not need energy to create a force so if you went to zero kelvins and used a superconductor that had zero resistance and a large current with almost no potential difference, the the crane would work with almost zero power supply. But up here at 20deg C mankind has no way to make current without forcing the electricity through a resistive conductor. ALL the electrical energy is used to overcome the resistance, just like in a toaster. ALL the electrical energy therefore goes to heat. I remind you that no work whatsoever is done on the tonne of metal hanging on the crane
All agreed, except two things. First, it isn't a given that the big fin accelerates more slowly. When you have the effectively unlimited power of hydraulics you can accelerate/decelerate a big fin fast, all day long. You'd be amazed how fast my fins move. As they move from out past the chine back in to under the hull they can leave a huge dustbin sized conical hole in the water that fills with a whirl pool. It's quite a sight
Yep, it isn't a given that bigger fins as such can't accelerate faster, but according to Mr.CMC electric motors are faster AOTBE, i.e. also with the same fin size.
Now that really is marketing BS. AOTBE, they are the same speed!
. More marketing BS. Sure they say they get the same result, but you don't actually believe them surely? As I said you can indeed get the same result with 50% of the fin size, but for 50% of the time. Maybe, just maybe, the real reason they use smaller fins because they can't dissipate the heat created by using larger ones
It sure is a biggie, at least in my experience and imho. I had plenty of times in Match1 when the anchorage wasn't so awful that I needed to leave, and perhaps didn't want to leave for whatever reason like lunch wasn't finished, but the stabs were using their full angular stroke to keep the boat still. Also when you do decide you want to run for cover, but you have say the tender to recover, you're glad of 100% worth of stab effect not 50%
I can't explain it any better but if you don't see that no work is being done in a stationary system then you don't see it. And of course electromagnet cranes don't get as hot as toasters: the current density is nothing like that of a toaster element plus have cooling fins or whatever is needed to dump the heatOn the matter of heat, I still fail to understand how part of those 50A can't be absorbed by the need to keep the magnetic field active, and I've never seen an electromagnet getting as red hot as a toaster, anyway.
But I'll rather give up, you seem convinced of what you're saying and I know that you wouldn't, unless supported by good reasons...
C'mon J, 'twas obvious that I (not Mr.CMC) used "AOTBE" in that context just to mean for any given fin size.
Now, show me when I told that I believe everything they say.
C'mon J, 'twas obvious that I (not Mr.CMC) used "AOTBE" in that context just to mean for any given fin size.
Actually, he also mentioned the max rotational speed of their electric system vs. the faster hydraulic system, but I can't remember the numbers.
The difference was relevant anyway, like 30% or so higher, and it didn't depend on the fin size.
Now, show me when I told that I believe everything they say.
I'm the one who always pointed out that there's only one way to check their claims, and it's to try the pudding.
Though in this respect, as Bart can confirm, I suggested him (even before this thread started) to take more time for such an important and expensive upgrade, postponing it to the end of the season, which would have given him more time to evaluate all the details.
Otoh, it seems to me that you're now constantly raising the BS flag and insisting on the heat issue just for the sake of it, as I'd rather expect from a Sleipner salesman at a boat show.
I see no reason why - in principle - IF a system can keep the rolling at bay more promptly than another one, a shorter timeframe shouldn't be sufficient to achieve a comparable result.
Besides, Bart told us (I didn't discuss that personally with Mr.CMC) that their SMALLER motor is used to drive either a 0.6 or a 0.8 Sq.M fin, but they only install the latter on the SL82.
So, bigger boat, bigger fins, and the same motor.
Do you recon that they could as well get rid of the onboard heating, and use pipes to route the heat from the stab motors throughout the boat?
. I'm not being a sleipner salesman (though, since you ask, their equipment is fantastic and I strongly recommend it 
) and have agreed with BartW that electric stabs make perfect sense for BA. I just think with an investment like this it is important to cut through marketing BS. The claim that there is no heat because the gearbox is a swiss watch is proper first grade BS, though in view of the fact you are struggling to digest where the energy flows are in an electromagnetic system (which includes a motor) and you're smarter than any stab factory engineer I should perhaps forgive them for that. Furthermore, as everyone has said, heat aint a propblem so long as you can get rid of it
Quick update,
The GRP bottom thickness is only 16mm, but this is at its minimum,
A lot of the surface (>70%) is more,
in the corners joining the stringers and the frames thickness varies between 20…25mm
stringers (longitude beams ? ) approx. 100mm x 100mm are spaced at 47cm between them.
frames (L-R beams ?) are 17cm wide, and up till floor level (70cm high above the keel In the master cabin.)
these are spaced 900mm, and some of them are closer,
ao the space we need in the bathroom / dressing room , there is 67cm space between the two frames.
The ultrasound measuring tool didn’t give accurate or reliable measurements on GRP,
don’t have time to find out why, It didn’t work accurate on GRP nowhere,
perhaps with the glass fibress inside, different materials ?
no time for further investigation..
The knitting needles gave a reliable measurement
Just because lots of people do something doesn't make it a smart thing to do. Ferretti, a generally fine yachtbuilder, tells its customers (including 94 footers) that its Mitsubishi ARGs are the best thing and recommends folks to buy ARG, and the customers say yes. But fact is ARG is inferior to Seakeeper - out here in the objective world of interim forums we all know that. Also, Ferretti did an inhouse test of brightness of a Lumishore vs their standard fit Xenon, and the chief of whatever department is was concluded the Xenon was brighter. Now, there is no room for subjectivity here becuase counting lumens is a bit like counting Euros, so you have to conclude they decided the answer they wanted before they did the test. Perhaps someone in the foodchain prefers to buy from their current supplier, for some reason.
That sounds a good plan imho. Only thing is that I wouldn't use the wood idea unless threy are sure they can press it onto the wet GRP with enough force to get a great bond. Lots of weights or vacuum bag. And, they must be certain that the wet surface of the GRP is flat which means the must lay the glass in carefully cut patches to "fill in" the 20mm zone and bring it up to the level of the thicker zones near the frames and stringers. If there is any doubt about achieving all this, forget the wood and used solid GRP. Mine are solid GRP and I'm much happier with that than a plywood core
Agreed, this is not what all of us expect from this forum. In fact, this is not what I was suggesting, by all means.
