Tuesday, December 31, 2013

Re: [Electric Boats] RE: system questions

 

16.7mm^2   Is only 5 AWG,   I used 00 AWG  on my 15 foot run to my Quattro 5000. The manual for my Victron Quattro in table 4.2 recommends 1x 70mm^2 for a 5 meter run. 

You are well under that.  After buying three of the best inverters on the market why skimp on cable?  The charger on the Quattro can charge at 70 amps for hours.  00 battery cable is not that expensive!  

On Dec 31, 2013, at 4:02 AM, Julian Webb <julian.proto@gmail.com> wrote:

 

I sized and fused the cabling to suit the usage, not what could be derived from the batteries.
I have:
+ around 1700 ah at 48vdc battery  bank in 3 banks
+ have 3 Quattros 8 kw each hooked up in 3 phase
+ total system max amperage demand of 100 amps a bank.

So used single 16mm2 for all confections within banks and 2x16mm2 welding flex (2 @ positive and negative) from each back to dc distribution point maximum run 5 metres, fused 200 amp.
Although a single 16mm should and did handle 100 amps easily over a lousy 5 metres, and despite getting barely warm (it was probably me holding them that made them warmer) there was a 1 volt drop difference between 1 and 2 using a single 16mm welding flex.
So on the belts and braces principle I used fig 2 hookup and doubled up the 16mm output from each bank and I'm not sure I can see any built drop especially as the Quattros and then the VSDs controlling the 3 phase motors have an adjustable ramp up/soft start facility.

Logically the figure 2 hookup must give better current flow within and from a bank.
I was the national service manager for a large pump company for years and the  electrical to water flow,  resistance to fiction analogy works in most situations and would be borne out here you'd think.

On 30 Dec 2013 13:36, "Roger L" <rogerlov@ix.netcom.com> wrote:
 

"I tested fig 1 against 2 and the difference was huge."
 
Interesting....and the difference in hoop up schemes has to become even more important as the connecting wire diameter goes down. Just curious: what size copper are you using?
  Roger L.
 
----- Original Message -----
Sent: Monday, December 30, 2013 1:06 AM
Subject: Re: [Electric Boats] RE: system questions

Hi

I have my 24 blocks, (4 in series then 2 of those in parallel, then 3 of those in parallel as I have 3 boxes of eight) hooked up as per fig 2.
I tested fig 1 against 2 and the difference was huge. Didn't bother with anything more complicated.
I have been told by two marine electricians and a solar installer that fig 1 type is good enough for 9 out of 10 situations, which is a real worry. Especially as fig 2 is so easy to do.
It does make you wonder about guys who "do this for a living".

Cheers

On 29 Dec 2013 17:03, "Roger L" <rogerlov@ix.netcom.com> wrote:
 

Nice article, Julian. I agree. Reading through it, we can see at a glance - once you tumble to the initial idea - (and isn't that always the truth of things....it's easy once you see it).  Anyway, near as I can tell, it looks like SmartGauge's way of hooking up the batteries to balance lead resistance is also the theoretically correct way to balance the battery drain.
 
And even though his theory checks with my own understanding, I was surprised to see how large the difference was... in spite of his using huge, short copper wire for leads between batteries.
I mean....who really uses huge 1 3/8" diameter stranded copper wire for their battery interconnecting cables? And who consistently keeps the length to be exactly 8" each? 
It's nice that he gives the constants that he uses. I also agree that even if the theory checks, the magnitude of the difference is surprisingly large. Someone should check on his figures just for a "reality check. Be easy enough to do it in a spreadsheet.  
 
Hmmm....it occurs to me that there's a quick arithmetic check possible and the advantage is that it uses the numbers that SmartGauge is reporting. Since the unbalanced batteries in Fig 1 and the balanced drain configuration in Fig 2 requires the use of slightly more cable in Fig 2 as he drew it., then the sum of currents in Fig2 should be higher as well.  
That only works because he is using a constant .02 ohms in the calculations (for each internal battery resistance).
 
So....by using his own numbers to check - and assuming that his wiring calcs match his sketch - the sum of the drain in Fig 2 should be MORE than the sum of Fig 1 by some small amount simply because the wires are longer.
 
Fig1 Sum = 35.9+26.2+20.4+17.8 = 100.3 amps
Fig2 Sum = 26.7+23.2+23.2+26.7 = 99.8 amps
 
Oops....Hmmm....it doesn't check!! Did I copy something wrong?  No....apparently not. What's going on here?
Still, if I was putting batteries in parallel I'd wire in keeping with Fig2. Betting that's pretty much the standard for batteries in parallel. 
    Roger L.     F-28cc 
 
----- Original Message ----- From: Julian Webb
Sent: Sunday, December 29, 2013 2:49 AM
Subject: Re: [Electric Boats] RE: system questions

Hi

While 48 volts makes built drop less of an issue than 12 or 24 volts, it's still incredibly important especially as the current goes up.
I have a 48 built system with 24 x 220ah blocks and we serised/paralleled them up two different ways just to check and were stunned at the difference, and I'm almost ashamed to admit I've worked in the  electrical industry for years BUT as the attached article says when you're used to working with 110/220 it's seldom an issue.
Armchair experts will tell you "what difference can it make", please read the attached article and remember that theory is where you should start but practice I'd where you must finish so listen to both. Cheers

On 29 Dec 2013 08:24, "Sheya" <sheyagiggles@yahoo.com> wrote:
 

Hey Mike,
Thanks for the response. I believe that since we have 8 (12V 200AH blocks) that would mean we have a total of 400AH at 48V. Would you agree thats right? We would have 2 blocks of 4 in series and those 2 blocks connected in parallel, does that make sense?
Sheya and Jason

From: "mike@electricyachtssocal.com" <mike@electricyachtssocal.com>
To: electricboats@yahoogroups.com
Sent: Friday, December 27, 2013 6:45:01 AM
Subject: [Electric Boats] RE: system questions

 
I am surprised no one has responded to your inquiry and hope this will stimulate others.  I know of at least two conversions of heavy displacement Morgan 41s by members of this group and they should have good advice for you.  I believe this is the proposed system and your usage:
 
The motor is a continuous rated 15hp that is to say 11,200 continuous rated and likely about 12hp to the shaft.  The boat is a Morgan 41 which often was supplied with a 45hp motor that likely drove at peak 30hp to the shaft.
The battery size is 200AH at 48v
You are looking to sail the boat as far as Alaska from your BC location. 
This is what our computer projection says and I would encourage all vendors to share your projections for this boat. 
Speed & Power
Kts-Watts
2.3-480
2.9-960
3.6-1920
4.6-3840
5.3-5760
5.8-7680
6.4-12480
6.8-17760
Hull speed 7.93
Your motor should push the boat at about 6.2kts in calm and likely about 4.5 in a mixed sea state and about 3kts against a poor sea state.  The 200AH battery bank will push the boat at an 80% dod for about 22NM at 3kts and 14NM at 4kts.
Mike
Electric Yacht of Southern California


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Re: [Electric Boats] safety concerns of batteries in parallel

 

HI Richard,


Its more than likely that you will be ok, but there are instances when batteries fail within 3 years and you have 8 of them.    What kind of batteries do you have?   Do you have 2 chargers or 8 chargers in your system.   If you send me a diagram of your system I can give it a quick review.   

It is possible to run the system on 96 volts but then you would need to change your charger(s) and your controller and add a ground fault monitor and that would be overly expensive.     

I have been working on a double diode block housed in an aluminum box that will work for an application like yours.   I will finish it off and test it in the early part of January and let you know when it is available.    It is quite simple to install with a terminal for each battery, the loads, and the charging sources.    The primary battery has to be hooked up directly to the controller and the charging sources,  with the auxiliary battery hooked up through the diodes.   The reason is the controller and charging sources must be able to see the battery.   If there is a diode between the main battery and the controller or the charging sources, these components can't see the battery to know its voltage and the regen function of the controller can't work.   Additionally, the controller could fail if there is a diode between it and the battery because there would be no place to put the regen energy and you would likely fry the mofsets or the capacitors.  

The simple and safe solution will be the dual battery diode block coming next year. 

Happy New Year to all! 

James 





On Dec 31, 2013, at 4:32 PM, R&M wrote:

 

James we have 2 48 volt strings in parallel. If I covered to series how could I run a 48 volt system on 96 volts. Currently the batteries are individually charged from shore power and only charged as a string during Regen or trickle charged from 90 watts solar. The interconnecting wires between batteries were kept equal length for equal discharge. Approaching our 3Rd season should we be concerned.
Richard




Sent from Samsung mobile

Robert Lemke <robert-lemke@att.net> wrote:
 

Nice write up. I've built EVs and off grid power solutions and have always chosen a series string at the voltage and a-hr capacity needed. For off grid it would typically be a 48 VDC bank for feeding the inverter made up of (24) 2 volt cells (700 a-hr to 2400 a-hr). For EVs I have switched to LiFePO4 3.2 volt cells and same for boat housebanks.

Bob

From: James Lambden <james@electroprop.com>
To: electricboats@yahoogroups.com
Sent: Tuesday, December 31, 2013 8:23 AM
Subject: [Electric Boats] safety concerns of batteries in parallel



James here, owner of Propulsion Marine and Electroprop.   

I have read several posts lately about batteries in parallel and there is a real safety issue here.

As Santa Barbara's marine electrician for the last 14 years, I have seen at least a dozen failures of batteries in parallel causing thermal issues.

This is a common issue as most boats are built today using 12 volts and to increase the ampacity of their battery banks, batteries are installed in parallel.    Just because this has been a common practice for years does not make it right or safe. 

The issue is when the battery gets an internal short in one of the cells.   The short is then driven by the other battery held in parallel.   It only takes about 10 amps to drive a short to the point of a thermal so it is not possible to protect the battery with a fuse.   The issue happens most commonly at the end of a batteries life.  

A lead acid battery can get so hot that it catches fire or explodes.   This I have personally witnessed as I have been there to diffuse the situation several times and believe me it can be very scary.   

Typical chargers do not have thermistors for all of the batteries and are not monitoring for the thermal condition on each individual battery.  

If you have batteries in parallel, then be sure to keep them out of parallel when the boat is not being monitored.   Batteries in parallel should be charged independently.   If you are hooking up one charger to multiple batteries, the second battery should be hooked through a diode block for the charging, and a second diode block for the loads.   There is a 1/2 volt drop in the diode block so it must be heat sinked.   On 48 to 96 volt battery banks, this half volt drop is not significant enough to cause a charging problem.   Set the charger up on the main battery at 1/4 volt more than recommended and the auxiliary battery will then function at 1/4 volt less than recommended.   On a 48 volt battery this works out to .125 volt difference in charging at the 12 volt battery level.   

When recombining batteries in parallel to operate your boat be sure that the battery banks are of a similar voltage or the switch can handle the current that will flow from a fully charged battery to a fully depleted battery.     If the batteries are of a dissimilar voltage then either charge up the low battery, or put a load on the high battery while you combine them.  

It doesn't matter which way you hook the batteries up, there is an issue every way you can hook them up.

If you want a bigger battery bank use a 6 volt or a 2 volt cell -  Lifeline batteries have great 2 volt, 1200 amp hour batteries.

It is ok to hook cells up in parallel and we see this done frequently with Lithium batteries.   Cells will work well in parallel because they don't have the higher potential to drive a short.   If you look inside a cell, the plates are hooked in parallel anyway, so joining another cell in parallel is fine.   You could also safey hook up 2 volt batteries in parallel because a 2 volt Lead Acid battery is a cell.     

Building a bigger battery bank can also be accomplished by increasing the voltage of the system so the batteries remain in series.    System voltages up to 100 volts are still very safe.   Just be sure to add a ground fault monitor on both the positive and negative of the battery bank, and keep the battery floating (not hooked to ground)   

The great thing about electric boats is we can build big batteries in series and avoid the parallel issues that are troublesome and dangerous on a typical 12 volt diesel boat.    This is one more reason why switching to electric can make your boat safer.   



James    




James Lambden
The Electric Propeller Company
625C East Haley Street,
Santa Barbara, CA
93103

805 455 8444 
jlambden:  Skype













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Re: [Electric Boats] safety concerns of batteries in parallel

 

James we have 2 48 volt strings in parallel. If I covered to series how could I run a 48 volt system on 96 volts. Currently the batteries are individually charged from shore power and only charged as a string during Regen or trickle charged from 90 watts solar. The interconnecting wires between batteries were kept equal length for equal discharge. Approaching our 3Rd season should we be concerned.
Richard




Sent from Samsung mobile

Robert Lemke <robert-lemke@att.net> wrote:
 

Nice write up. I've built EVs and off grid power solutions and have always chosen a series string at the voltage and a-hr capacity needed. For off grid it would typically be a 48 VDC bank for feeding the inverter made up of (24) 2 volt cells (700 a-hr to 2400 a-hr). For EVs I have switched to LiFePO4 3.2 volt cells and same for boat housebanks.

Bob

From: James Lambden <james@electroprop.com>
To: electricboats@yahoogroups.com
Sent: Tuesday, December 31, 2013 8:23 AM
Subject: [Electric Boats] safety concerns of batteries in parallel



James here, owner of Propulsion Marine and Electroprop.   

I have read several posts lately about batteries in parallel and there is a real safety issue here.

As Santa Barbara's marine electrician for the last 14 years, I have seen at least a dozen failures of batteries in parallel causing thermal issues.

This is a common issue as most boats are built today using 12 volts and to increase the ampacity of their battery banks, batteries are installed in parallel.    Just because this has been a common practice for years does not make it right or safe. 

The issue is when the battery gets an internal short in one of the cells.   The short is then driven by the other battery held in parallel.   It only takes about 10 amps to drive a short to the point of a thermal so it is not possible to protect the battery with a fuse.   The issue happens most commonly at the end of a batteries life.  

A lead acid battery can get so hot that it catches fire or explodes.   This I have personally witnessed as I have been there to diffuse the situation several times and believe me it can be very scary.   

Typical chargers do not have thermistors for all of the batteries and are not monitoring for the thermal condition on each individual battery.  

If you have batteries in parallel, then be sure to keep them out of parallel when the boat is not being monitored.   Batteries in parallel should be charged independently.   If you are hooking up one charger to multiple batteries, the second battery should be hooked through a diode block for the charging, and a second diode block for the loads.   There is a 1/2 volt drop in the diode block so it must be heat sinked.   On 48 to 96 volt battery banks, this half volt drop is not significant enough to cause a charging problem.   Set the charger up on the main battery at 1/4 volt more than recommended and the auxiliary battery will then function at 1/4 volt less than recommended.   On a 48 volt battery this works out to .125 volt difference in charging at the 12 volt battery level.   

When recombining batteries in parallel to operate your boat be sure that the battery banks are of a similar voltage or the switch can handle the current that will flow from a fully charged battery to a fully depleted battery.     If the batteries are of a dissimilar voltage then either charge up the low battery, or put a load on the high battery while you combine them.  

It doesn't matter which way you hook the batteries up, there is an issue every way you can hook them up.

If you want a bigger battery bank use a 6 volt or a 2 volt cell -  Lifeline batteries have great 2 volt, 1200 amp hour batteries.

It is ok to hook cells up in parallel and we see this done frequently with Lithium batteries.   Cells will work well in parallel because they don't have the higher potential to drive a short.   If you look inside a cell, the plates are hooked in parallel anyway, so joining another cell in parallel is fine.   You could also safey hook up 2 volt batteries in parallel because a 2 volt Lead Acid battery is a cell.     

Building a bigger battery bank can also be accomplished by increasing the voltage of the system so the batteries remain in series.    System voltages up to 100 volts are still very safe.   Just be sure to add a ground fault monitor on both the positive and negative of the battery bank, and keep the battery floating (not hooked to ground)   

The great thing about electric boats is we can build big batteries in series and avoid the parallel issues that are troublesome and dangerous on a typical 12 volt diesel boat.    This is one more reason why switching to electric can make your boat safer.   



James    




James Lambden
The Electric Propeller Company
625C East Haley Street,
Santa Barbara, CA
93103

805 455 8444 
jlambden:  Skype










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Re: [Electric Boats] safety concerns of batteries in parallel

 

Nice write up. I've built EVs and off grid power solutions and have always chosen a series string at the voltage and a-hr capacity needed. For off grid it would typically be a 48 VDC bank for feeding the inverter made up of (24) 2 volt cells (700 a-hr to 2400 a-hr). For EVs I have switched to LiFePO4 3.2 volt cells and same for boat housebanks.

Bob

From: James Lambden <james@electroprop.com>
To: electricboats@yahoogroups.com
Sent: Tuesday, December 31, 2013 8:23 AM
Subject: [Electric Boats] safety concerns of batteries in parallel



James here, owner of Propulsion Marine and Electroprop.   

I have read several posts lately about batteries in parallel and there is a real safety issue here.

As Santa Barbara's marine electrician for the last 14 years, I have seen at least a dozen failures of batteries in parallel causing thermal issues.

This is a common issue as most boats are built today using 12 volts and to increase the ampacity of their battery banks, batteries are installed in parallel.    Just because this has been a common practice for years does not make it right or safe. 

The issue is when the battery gets an internal short in one of the cells.   The short is then driven by the other battery held in parallel.   It only takes about 10 amps to drive a short to the point of a thermal so it is not possible to protect the battery with a fuse.   The issue happens most commonly at the end of a batteries life.  

A lead acid battery can get so hot that it catches fire or explodes.   This I have personally witnessed as I have been there to diffuse the situation several times and believe me it can be very scary.   

Typical chargers do not have thermistors for all of the batteries and are not monitoring for the thermal condition on each individual battery.  

If you have batteries in parallel, then be sure to keep them out of parallel when the boat is not being monitored.   Batteries in parallel should be charged independently.   If you are hooking up one charger to multiple batteries, the second battery should be hooked through a diode block for the charging, and a second diode block for the loads.   There is a 1/2 volt drop in the diode block so it must be heat sinked.   On 48 to 96 volt battery banks, this half volt drop is not significant enough to cause a charging problem.   Set the charger up on the main battery at 1/4 volt more than recommended and the auxiliary battery will then function at 1/4 volt less than recommended.   On a 48 volt battery this works out to .125 volt difference in charging at the 12 volt battery level.   

When recombining batteries in parallel to operate your boat be sure that the battery banks are of a similar voltage or the switch can handle the current that will flow from a fully charged battery to a fully depleted battery.     If the batteries are of a dissimilar voltage then either charge up the low battery, or put a load on the high battery while you combine them.  

It doesn't matter which way you hook the batteries up, there is an issue every way you can hook them up.

If you want a bigger battery bank use a 6 volt or a 2 volt cell -  Lifeline batteries have great 2 volt, 1200 amp hour batteries.

It is ok to hook cells up in parallel and we see this done frequently with Lithium batteries.   Cells will work well in parallel because they don't have the higher potential to drive a short.   If you look inside a cell, the plates are hooked in parallel anyway, so joining another cell in parallel is fine.   You could also safey hook up 2 volt batteries in parallel because a 2 volt Lead Acid battery is a cell.     

Building a bigger battery bank can also be accomplished by increasing the voltage of the system so the batteries remain in series.    System voltages up to 100 volts are still very safe.   Just be sure to add a ground fault monitor on both the positive and negative of the battery bank, and keep the battery floating (not hooked to ground)   

The great thing about electric boats is we can build big batteries in series and avoid the parallel issues that are troublesome and dangerous on a typical 12 volt diesel boat.    This is one more reason why switching to electric can make your boat safer.   



James    




James Lambden
The Electric Propeller Company
625C East Haley Street,
Santa Barbara, CA
93103

805 455 8444 
jlambden:  Skype










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RE: [Electric Boats] Generating electricity from an electric motor while sailing

 

Yes we are talking Apples and Oranges here.
Smaller boats are capable of producing Regenerative power at proportionate numbers to the size of their power plants. I run a 144V system and use less Amperage proportionately to a 48V or 72V system. I run an 18" prop and no transmission (thank god). I also have a 41' water line and might loose 1/2 knot do to my props dragging. But a boat with a fixed in water prop and an ICE will loose even more so I find the argument that "it slows the boat down" to regenerate power not to be in my case. At 8 knots I could care less about being a 1/2 knot slower. As for PV panels I wouldn't put the number of panels I would have to install for a 144V system on my boat however I will put panels on to remove the load off of the Propulsion bank going to the House bank. No generator is needed, the motors themselves are the generators however I have a genset on board to extend the run time to whatever I carry in fuel.
The Gunboats and a few other BIG (Tang) cats have used them and when installed properly work great. With the LiFePo4's I'll install in the future weight won't be an issue anymore and I'll hopefully gain 1 or 2 knots in speed. But heck I have a Condo on water so speed wasn't ever a factor anyway.
8O)

Steve in Solomons MD

About 100W may be sometimes produced, at cost of 200W - 1000W in drag.
100W is too little to bother with.

(It works very little, very poorly, for many reasons. Most companies who advertised it closed, and very few solutions are sold any more.
Like towed generators - its just not worth it.
Large PV panels produce much more energy, and are much less bothersome, and much cheaper.)

(Tehnically - it can work. But sailboat props are very inefficient for this, there is too much drag, and thus the real power produced is very very small).

A regen solution would work ok IF, for example you could -use a very large 3 m diameter prop designed and built for regen -use no transmission -use a special generator built for this

Efficiency has to do with area cubed, iirc, and speed to the third or fourth power. Thats why tidal stuff needs big props and fast currents.
Transmissions eat too much power in parasitic drag.
Generators dont work well at low rpm.

A towed generator might produce 1 kWhr over 24 hours in ideal conditions, maybe 1 day in 10.
Thats 100W for 10 hours, at best, delivered to battery.
Costing about 0.5 knots in speed.

A 300W solar panel will produce about 6 hours at 50% nominal, on 70% of days, or about 0.950 kWhr.
And over 1kWhr every day in sunny areas of the world. The UK counts as sunny, btw- during half the year.

All averages for normal typical 10-12 m sailboat, 6-7 knots max speed, small prop.
For the types discussed here, no-one advocates using these in 24 m long 6M$ sundeers from Dashew.

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RE: [Electric Boats] Generating electricity from an electric motor while sailing

 

Hi Chris,
You're talking about REGENERATIVE power and yes we can produce some makeup power with it. The thing is we can't generate enough in a short enough time to really make it worth while however on my 41' cat I can generate plenty while on a 24hr or longer trip. If I'm just putzing around the bay for the day I can make up the power I used to get off the dock or what power I use which isn't much so in effect go sailing using zero power.

Steve in Solomons MD

I am no expert on electric motors and power. My basic understanding is that turning over an electric motor can produce electricity. I realise is can be a complex business - depending on whether the motor is induction, brushed etc, AC or DC, the revs and gearing needed etc.

Pretty useful thing for sail boats though, using an existing electric motor to be able to charge batteries while under sail.

I have a Farrier F-31 (see www.fleetwing.com.au) which I only motor in and out of dock or on the rare occasion when there is no wind here in Tasmania. I much prefer to sail. This trimaran has different characteristics to a monohull (greater range of speed and less tolerance of weight). This sort of battery charging configuration would especially suit a monohull where batteries could provide very useful ballast down low in the boat, and where speed has a lesser range.

I have not been able to find any posts on this topic yet, can anyone help?

Cheers,

Chris Wilson
Abels Bay, Tasmania

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Re: [Electric Boats] Generating electricity from an electric motor while sailing

 

This is called regen.
In short - it does not work in the real world.

About 100W may be sometimes produced, at cost of 200W - 1000W in drag.
100W is too little to bother with.

(It works very little, very poorly, for many reasons. Most companies who
advertised it closed, and very few solutions are sold any more.
Like towed generators - its just not worth it.
Large PV panels produce much more energy, and are much less bothersome,
and much cheaper.)

(Tehnically - it can work. But sailboat props are very inefficient for
this, there is too much drag, and thus the real power produced is very
very small).

A regen solution would work ok IF, for example you could
-use a very large 3 m diameter prop designed and built for regen
-use no transmission
-use a special generator built for this

Efficiency has to do with area cubed, iirc, and speed to the third or
fourth power. Thats why tidal stuff needs big props and fast currents.
Transmissions eat too much power in parasitic drag.
Generators dont work well at low rpm.

A towed generator might produce 1 kWhr over 24 hours in ideal
conditions, maybe 1 day in 10.
Thats 100W for 10 hours, at best, delivered to battery.
Costing about 0.5 knots in speed.

A 300W solar panel will produce about 6 hours at 50% nominal, on 70% of
days, or about 0.950 kWhr.
And over 1kWhr every day in sunny areas of the world. The UK counts as
sunny, btw- during half the year.

All averages for normal typical 10-12 m sailboat, 6-7 knots max speed,
small prop.
For the types discussed here, no-one advocates using these in 24 m long
6M$ sundeers from Dashew.

On 31/12/2013 05:40, Christopher wrote:
> Pretty useful thing for sail boats though, using an existing electric
> motor to be able to charge batteries while under sail.
>
> I have a Farrier F-31 (see www.fleetwing.com.au) which I only motor in
> and out of dock or on the rare occasion when there is no wind here in
> Tasmania. I much prefer to sail. This trimaran has different
> characteristics to a monohull (greater range of speed and less
> tolerance of weight). This sort of battery charging configuration
> would especially suit a monohull where batteries could provide very
> useful ballast down low in the boat, and where speed has a lesser range.
>
> I have not been able to find any posts on this topic yet, can anyone help?
>
> Cheers,
>
> Chris Wilson
> Abels Bay, Tasmania

--
-hanermo (cnc designs)

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[Electric Boats] safety concerns of batteries in parallel

 

James here, owner of Propulsion Marine and Electroprop.   

I have read several posts lately about batteries in parallel and there is a real safety issue here.

As Santa Barbara's marine electrician for the last 14 years, I have seen at least a dozen failures of batteries in parallel causing thermal issues.

This is a common issue as most boats are built today using 12 volts and to increase the ampacity of their battery banks, batteries are installed in parallel.    Just because this has been a common practice for years does not make it right or safe. 

The issue is when the battery gets an internal short in one of the cells.   The short is then driven by the other battery held in parallel.   It only takes about 10 amps to drive a short to the point of a thermal so it is not possible to protect the battery with a fuse.   The issue happens most commonly at the end of a batteries life.  

A lead acid battery can get so hot that it catches fire or explodes.   This I have personally witnessed as I have been there to diffuse the situation several times and believe me it can be very scary.   

Typical chargers do not have thermistors for all of the batteries and are not monitoring for the thermal condition on each individual battery.  

If you have batteries in parallel, then be sure to keep them out of parallel when the boat is not being monitored.   Batteries in parallel should be charged independently.   If you are hooking up one charger to multiple batteries, the second battery should be hooked through a diode block for the charging, and a second diode block for the loads.   There is a 1/2 volt drop in the diode block so it must be heat sinked.   On 48 to 96 volt battery banks, this half volt drop is not significant enough to cause a charging problem.   Set the charger up on the main battery at 1/4 volt more than recommended and the auxiliary battery will then function at 1/4 volt less than recommended.   On a 48 volt battery this works out to .125 volt difference in charging at the 12 volt battery level.   

When recombining batteries in parallel to operate your boat be sure that the battery banks are of a similar voltage or the switch can handle the current that will flow from a fully charged battery to a fully depleted battery.     If the batteries are of a dissimilar voltage then either charge up the low battery, or put a load on the high battery while you combine them.  

It doesn't matter which way you hook the batteries up, there is an issue every way you can hook them up.

If you want a bigger battery bank use a 6 volt or a 2 volt cell -  Lifeline batteries have great 2 volt, 1200 amp hour batteries.

It is ok to hook cells up in parallel and we see this done frequently with Lithium batteries.   Cells will work well in parallel because they don't have the higher potential to drive a short.   If you look inside a cell, the plates are hooked in parallel anyway, so joining another cell in parallel is fine.   You could also safey hook up 2 volt batteries in parallel because a 2 volt Lead Acid battery is a cell.     

Building a bigger battery bank can also be accomplished by increasing the voltage of the system so the batteries remain in series.    System voltages up to 100 volts are still very safe.   Just be sure to add a ground fault monitor on both the positive and negative of the battery bank, and keep the battery floating (not hooked to ground)   

The great thing about electric boats is we can build big batteries in series and avoid the parallel issues that are troublesome and dangerous on a typical 12 volt diesel boat.    This is one more reason why switching to electric can make your boat safer.   



James    




James Lambden
The Electric Propeller Company
625C East Haley Street,
Santa Barbara, CA
93103

805 455 8444 
jlambden:  Skype






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