Team Peruagus (University of Southampton)
gdp...@gmail.com
Hello everyone,
we are Team Peruagus from the University of Southampton. We are a group of 6 students and, as part of our masters program, are attempting a transatlantic crossing under the regulations of the Microtransat Challenge.
We started this project less than three weeks ago and we would already like to thank everyone, who is sharing information in this forum, for doing so (special thanks to Team Joker for answering our emails!). It is very valuable to new teams like ours and allows us to not repeat every mistakes that has already been made.
One thing probably making us stand apart from the majority of teams of the Microtransat Challenge is our decision to enter the non-sailing class, as we have decided to not rely on wind power 100%, but are considering solar as our main source of energy.
We are very happy to share information with all other teams and we are in the process of setting up a facebook page documenting our project. We will share a link to the page here.
Any questions, please comment on here or send us an email.
Team Peruagus
PS: Peruagus (lat. World Traveller)
andy
Colin Sauze
Google some motorboat projects outside Microtransat: Solar Voyager, Scout Transatlantic, SolarSurfer and SeaCharger. The first two had some problem with the rudder. SolarSurfer reported problems with thruster entanglement - don't use a ducted propeller. SeaCharger did amazing job, their design is inspirational. I have no doubts that a properly designed motorboat would cross the ocean, but I have doubts that it would navigate to the target point within a 50km radius. You can't fit more than 200W solar power on the 2-metre boat, so it won't be faster than specific ocean currents in the Atlantic that don't always flow in your direction. When I started building a motorboat and I realized that it would act more like a "floating log", I have given up and I started building a sailboat. Just my thoughts. You may have better ideas how to build a reliable and fast enough motorboat.
I do share Andy's concerns that you might struggle to get enough energy from your solar panels to navigate accurately. Have you considered some kind of hybrid system like the C-Enduro (https://www.asvglobal.com/product/c-enduro/) uses?
Colin.
Peter van den Brand
I have been toying with the idea to build a solar boat as well. I did some calculations to figure out how many watts I'd need to keep a motor boat going at a reasonable speed for 24h a day. The calculation roughly went as follows:
- I want my boat to go approx 5 km/h, which is 2.7 knots (this is the theoretical hull speed for a 1.2m boat, so a sail boat wouldn't be going any faster)
- Compute drag for the hull at that speed:
- I found a model for hull drag in this paper:
https://www.scribd.com/document/346520042/Keuning-2008-pdf
- I found some more experimental results for an IOM yacht here: http://radiosailingtechnology.com/index.php/hulls/estimating-the-hull-drag-of-an-iom-yacht-august-2014
- Note that all these results are for a bare hull, but are all measured on small boats of around one meter long
- An IOM has a drag of roughly 2.5 newton at 2.7 knots
- My current sailing boat hull has a theoretical drag of around 3.3 newton at 2.7 knots (it is 1.3 meters long and is a lot heavier than an IOM)
- Multiply the dray by the speed (in m/s) to get the required
watts:
- 2.5 N * (5 / 3.6) = 3.5 watts
- Multiply the watts by 2 because power is lost in the "drive
train" (this is a big fudge factor, but could be reasonable
according to some posts I read on the internet)
- Multiply by a factor of 4 to 6 because you only get 4 to 6 hours of full sunshine per day on average
- So 3.5 * 2 * 6 = 42 watt peak required
If you're happy with a slightly slower speed, then the drag goes
down very quickly. An IOM only has a drag of 1 newton at 4.2 km/h.
That means just 17 watt peak of solar panels required to keep the
motor going 24 hours a day. In sunny parts (using a factor of 4
instead of 6) it would even be just 11.2 watt peak. Fitting around
25W on a 1.2 meter boat should be quite possible, and I'd expect
that boat to go somewhere between 4 and 5 km/h, which is more than
the approx 1-1.5 knots that ocean currents can be.
I haven't built any motor boats though, so I don't actually know whether the calculation is correct. Given the comments below, I must have missed something. Any idea whether I'm on the right track?
Thanks,
Peter
--
You received this message because you are subscribed to the Google Groups "Microtransat" group.
To unsubscribe from this group and stop receiving emails from it, send an email to microtransat...@googlegroups.com.
To post to this group, send email to microt...@googlegroups.com.
To view this discussion on the web, visit https://groups.google.com/d/msgid/microtransat/21ff57e9-842a-8123-bcd6-95c1e4b7d977%40aber.ac.uk.
For more options, visit https://groups.google.com/d/optout.
Chris Diacov
Hello Peter,
I don’t think you’ve missed anything. Your math is correct (or at least in the ball park) and is backed by real-life tests. I can confirm that with a fairly draggy configuration (cylindrical floats, 0.07m draft, 0.95m LWL) you can achieve sustained speed of 2.0+ knots at 9W (measured at the power source). Our Mk. III project daily power budget was 260Wh which was tested and confirmed on a single 50W panel (in the tropics, May – September).
Two (major) caveats:
- Speed measured in calm water. If you’ve ever sailed off-shore, you’ll know that this doesn’t translate well to ocean passage conditions;
- You can go significantly faster than that but power requirements go up with the square of speed;
For all intents and purposes, you can consider your solar harvest rate to be no more than 100W/sq.m. of solar panels (assuming highly efficient panels and optimal insolation). Fitting 0.25 sq.m. of solar panels on a 1m monohull is a tough job (but maybe not impossible).
And one final note on the navigation challenges with low speed vessels: whether sailing or motoring, very rarely the best route to your next waypoint is a straight line. If you build your course calculation logic based (solely) on that assumption, you are setting yourself for a serious disappointment :)
--
Chris, Project Pilotfish
To view this discussion on the web, visit https://groups.google.com/d/msgid/microtransat/6d67f677-d90a-e7fa-ac41-d28401791f57%40vdbrand.nl.
JOSE ANTONIO COZAR RIOS
About the catamaran solution I response my reflexión to Andy in the Last post. I think that is a bad idea.
Kim
Hi Peter,
I think your calculations seems sane and I don't think I can give you anything better, but... I think you should take a look at the following videos, if not already seen them.
Here's a good'ol salty bear that explains a good deal about
monohull vs. catamaran as discussed further down in this
conversation, but also some details about why a boat behaves the
way it does. Definitely interesting and very good explanation.
https://www.youtube.com/watch?v=G5JOuSuT-lI <--Monohull vs
Catamaran
https://www.youtube.com/watch?v=H8hvKZ73S0Q <-- Hull speed
Just a little contribution to the discussion.
/Kim
To view this discussion on the web, visit https://groups.google.com/d/msgid/microtransat/6d67f677-d90a-e7fa-ac41-d28401791f57%40vdbrand.nl.
Colin Sauze
On 2017-10-23 20:16, Peter van den Brand wrote:
I have been toying with the idea to build a solar boat as well. I did some calculations to figure out how many watts I'd need to keep a motor boat going at a reasonable speed for 24h a day. The calculation roughly went as follows:
- I want my boat to go approx 5 km/h, which is 2.7 knots (this is the theoretical hull speed for a 1.2m boat, so a sail boat wouldn't be going any faster)
- Compute drag for the hull at that speed:
- I found a model for hull drag in this paper: https://www.scribd.com/document/346520042/Keuning-2008-pdf
- I found some more experimental results for an IOM yacht here: http://radiosailingtechnology.com/index.php/hulls/estimating-the-hull-drag-of-an-iom-yacht-august-2014
- Note that all these results are for a bare hull, but are all measured on small boats of around one meter long
- An IOM has a drag of roughly 2.5 newton at 2.7 knots
- My current sailing boat hull has a theoretical drag of around 3.3 newton at 2.7 knots (it is 1.3 meters long and is a lot heavier than an IOM)
- Multiply the dray by the speed (in m/s) to get the required watts:
- 2.5 N * (5 / 3.6) = 3.5 watts
- Multiply the watts by 2 because power is lost in the "drive train" (this is a big fudge factor, but could be reasonable according to some posts I read on the internet)
- Multiply by a factor of 4 to 6 because you only get 4 to 6 hours of full sunshine per day on average
Also remember that in open ocean you can expect waves of 2-3m on average, so this is going to have significant effects on your speed. During a storm it might not even be worth trying to drive the motors.
- So 3.5 * 2 * 6 = 42 watt peak required
If you're happy with a slightly slower speed, then the drag goes down very quickly. An IOM only has a drag of 1 newton at 4.2 km/h. That means just 17 watt peak of solar panels required to keep the motor going 24 hours a day. In sunny parts (using a factor of 4 instead of 6) it would even be just 11.2 watt peak. Fitting around 25W on a 1.2 meter boat should be quite possible, and I'd expect that boat to go somewhere between 4 and 5 km/h, which is more than the approx 1-1.5 knots that ocean currents can be.
Note that selecting the right motor would be crucial. The motor would need to be relatively small, because it needs to produce less than 10W and the right RPM at its peak efficiency. Maxon has several motors that would fit the criteria, but they are quite expensive. Any motor that you buy for an RC boat is massively overpowered I think, and would be very inefficient to drive slowly.
My own experience in building a motorised boat is that it was quite inefficient in terms of converting electricity into forward motion, although this was building a much larger boat designed for going through ice so speed wasn't the key criteria for the hull design. There's a lot more detail about it in this paper, http://www.thejot.net/?page_id=837&show_article_preview=712&jot_download_article=712
Colin.
gdp...@gmail.com
adam.alc...@gmail.com
gdp...@gmail.com
We are approaching our detailed design phase now and were wondering if the microtransat waterline length includes a rudder attached at the end of the hull. According to the official definition of LWL, the rudder would not be included. However, we wanted to double check how microtransat is dealing with this. Does anyone know the regulations on this?
Thank you,
Julian
Team Peruagus
Paul Miller
"There are two classes of boat allowed:
- The sailing class permits only wind power for propulsion. The hull overall length (LOA) is restricted to two point four (2.4) metres.
- The non-sailing class permits any source of propulsion. The hull overall length (LOA)) is restricted to two point four (2.4) metres."
But later on it indicates it is LWL. The LWL is the old rule, the LOA is the current rule. (Colin, could you fix the confusion?)
LOA includes the rudder.
--
You received this message because you are subscribed to the Google Groups "Microtransat" group.
To unsubscribe from this group and stop receiving emails from it, send an email to microtransat+unsubscribe@googlegroups.com.
To post to this group, send email to microt...@googlegroups.com.
To view this discussion on the web, visit https://groups.google.com/d/msgid/microtransat/52338961-e89f-4565-a46d-03679cd2d366%40googlegroups.com.
Colin Sauze
Hi,There is a bit of an ambiguity in the rules as the top of the rules page it says,
"There are two classes of boat allowed:
- The sailing class permits only wind power for propulsion. The hull overall length (LOA) is restricted to two point four (2.4) metres.
- The non-sailing class permits any source of propulsion. The hull overall length (LOA)) is restricted to two point four (2.4) metres."
But later on it indicates it is LWL. The LWL is the old rule, the LOA is the current rule. (Colin, could you fix the confusion?)
LOA includes the rudder.
Colin.