Choosing A Marine Wind Charging System
Even the smoothest, quietest running generators still burn fuel, make noise, exhaust, vibration, heat, and demand that someone be aboard to operate and monitor these things most of the time. Modern, efficient alternative marine charging systems are available and capable of supplying reliable back-up and even primary power demands.
Cruising the Bahamas (some years ago) in a sailboat with an unreliable engine and minimal battery capacity, we rigged a hand-made propeller to an alternator and hung it from the stays. It was noisy and in need of constant adjustment, but it actually worked for a while until its own vibrations dismantled it. Things are better now. New technology provides efficient high-output alternators, quiet composite aerodynamic blades, and better mounting systems and control panels.
Loads on the batteries may consist of 12 volt, 24 volt, or 48 volt direct current (DC) equipment or alternatively a DC to AC inverter can be installed so that alternating current (AC) equipment can be supplied. The inverter can be selected to supply AC equipment of 110 volt or 220 volt, and 50 Hz or 60 Hz as appropriate. Direct battery charging configurations are typical in yachts, and the power can then be directed through an inverter as needed.
Check manufacturer's specifications for RPM outputs vs. wind speeds. When the wind blows, the rotor blade stops a percentage of the wind. That percentage is what is converted into energy. According to physics, the maximum amount of wind energy that can be converted is 59.3%.
This is known as the Betz Limit. Be sure to get a marine unit designed to withstand a wet and salt environment. Check also for the DB (sound level) output. A wind turbine that sounds like a helicopter can destroy that evening ambiance. And if you're planning for long range cruising, make sure you will have access to parts.
Sailboats are the most common beneficiaries of wind power since they do not need (or like) to run engines, and usually have smaller fuel capacities. When choosing a location for mounting your wind generator, keep in mind that the best mounting spots allow the generator a free and unobstructed flow of the wind while keeping the rotating blades a safe distance from any rigging or possible body contact.
Stern Pole - The most common mount used for a wind generator is a stern pole. These can be easily fabricated from aluminum pipe, mount the unit clear of the deck and rigging, and provide relatively easy access for servicing. They have the added advantage of leaving any noise downwind while at anchor.
Radar Arch - Another variation of the stern pole with a lot more versatility allowing easy mounting of many different pieces of cruising gear including wind generators, solar panels, antennas, and often a tender. On my catamaran the arch is also stowage space for a life raft, and provides a shade awning behind the cockpit.
Mast Mount - If your boat has two masts, you may want to consider mounting your wind generator either 2/3 of the way up on your aft mast, or all the way at the top. This location provides for much more wind and results in a cleaner looking deck. You can buy commercially available brackets or have one fabricated specifically for your purpose.
If you need to service your wind generator, however, this location can make the task quite challenging. Also, be aware of the added stress factor on the rigging.
Fore-triangle Hoist - If you just can't seem to find a suitable spot to mount a wind generator, you might want to consider hoisting it in the fore-triangle. Although it won't be usable underway, hoisting a generator on the foredeck while at anchor is a reasonable way to supplement on-board power. Some wind generators are designed to be deployed and stowed, and feature components that are easy to disassemble and store.
Now we need to wire everything up. To regulate current flow, most wind generators require a controller. A charge controller senses the state of charge of your battery bank and halts or redirects the output from the wind generator when your batteries reach full charge. Many charge controllers for wind generators redirect the charging current to a dummy load as your battery bank approaches a full charge.
The mounting location for your charge controller can be anywhere between the wind generator and the battery bank, but it is usually placed near the batteries for eas 00004000 e of wiring the voltage sensing leads.
The last step before actually seating the wind generator is to run your wiring from the generator to the charge controller and onto the battery.
Before you can do that, you need to determine what size wire you'll need. Wire size is a function of the amount of current the wire will carry along its round trip length from the generator to the batteries, and then back to the generator.
When you run the wiring through the deck, and for stern pole mounting plates, don't forget to waterproof any holes. High quality sealants such as 3M 101 or Sikaflex 291 will do the trick. Once inside the boat, your wiring will snake through lockers and maybe under headliners until it finally reaches your charge controller. If you're lucky, you may find an existing conduit running to your batteries or electrical panel area. Do some poking around first to see if one exists before drilling your own route for the wires.
At your charge controller you'll find several easy connections.
Two voltage sense leads will run to your batteries, the positive leads from your wind generator will connect to the positive input on your controller and the positive output from your controller will lead to your positive bus. In this positive output line, install an in-line fuse holder that will eventually house a fuse rated at 1.5 times the rated output of your wind generator, but don't insert the fuse yet. Your negative wire from the wind generator may or may not bypass the controller depending upon the model. It should eventually connect to your common electrical ground.
Your final connection is the one that is going to be made as you install and mount the wind generator itself. Connect the outputs from the wind generator to your already run wiring, and slide the generator onto the mount. Keep enough extra slack wiring to allow you to easily uninstall the unit in the future for servicing. Insert the above mentioned fuse, wait for the breeze, and you're in business.
Whether you plan to cruise the oceans, or your yacht waits at the mooring for your next time-off adventure; free, non-polluting wind turbine power keeps those batteries charged and ready to go.
Be Knowledgeable, Be Aware, and Be Safe. Happy Boating!
Detailed information on the Hush wind generator?
It is an Australian invention and should be released for sale soon.
Grid connect Controller for wind turbine driven induction generator (async motor)?
Thanks to your many very helpful answers to my previous questions I was able to find a company that sells such a device. As you may recall, I was intrigued by this device: http://www.clariantechnologies.com/main/page_home.html. It is a vertical axis wind turbine driven async motor that acts as an induction generator that plugs directly into an existing outlet in your home. No inverters, no batteries. Sales price around $500. With an electric meter (a freebie from our power company) than can run backwards, this would allow me to greatly reduce my energy bill all at a very low cost. To make the cost even cheaper, and to increase the power output, I want to make my own wind turbines, and use my own async motors. So all I need is the controller.
I have found a company that sells such a device: http://www.prairieturbines.com for $830. It connects a 5500 watt wind turbine driven async motor directly to the grid. No inverter, no batteries. It uses a “hall-device” to measure the RPM, it provides about 1 AMP to the motor to energize its coils, 50amp solid state “zero-cross relays”, capacitors, 30amp breaker/enclosure, an exterior mounted disconnect, and an interior-mounted fused-control voltage switch. This is it!!!
So my question is, does anyone know how to build this controller. This company doesn’t sell the plans to this, and $830 is too high for me. I am sure I could build this with components for less that $400. If there is any electrical engineering person out there that can help, this will be a challenge, but it is great knowing that someone already has figured this out and is selling it.
Solar vs. Wind power and how i can use it?
Okay I was on new egg checkin out some solar panels and noticed they have wind generators for sale on their site to money is no problem but like all folks i dont wanna spend more than i have too which should i buy solar or wind? which can get me the most electricity?? and does anyone know about how i can get my house to run on completely solar or wind?
Look at the Prairie Turbines site again. The price of the micro-controller including the hall device is $255. The $45 book provides a complete list of material and instructions to build everything else.
The micro-controller monitors the speed sensor and provides control signals to two solid-state relays. One relay connects the motor to the grid when the speed reaches the motor’s 1800 RPM synchronous speed and disconnects the motor if the speed drops below 1800 RPM. The other relay is energized to release the brake when the controller is energized and de-energized by the controller when the motor speed exceeds the maximum safe operating speed. If this occurs, the controller apparently must be manually reset.
I did not find the maximum safe operating speed stated on the web site. If the full load speed of the motor is 1750 RPM, the full load slip is 1800 minus 1750 or 50 RPM. The speed at which the motor would generate full load current and present full load torque to the turbine is 1800 RPM plus the full load slip or 1850 RPM. With the design described, a three-phase motor is connected to a single phase source with capacitors connected between the source and the third motor phase. That is likely to increase the motor slip somewhat.
I am not sure what happens if the motor is driven above the speed at which it generates full load current. A three-phase motor operating as an induction generator connected to a three-phase supply has a torque vs. speed curve that is something like the mirror image of the motoring torque vs. speed curve. The curve is likely different with the single-phase connection used in this case. I don’t know what the speed vs. current curve looks like in either case, but I will see if I can find it. I am also curious to know if the Alan Plunkett listed on the web site as an author is the Alan Plunkett that is well known author of technical papers on inverter and variable frequency drive subjects.
Added information:
I found information indicating that, for a 3-phase motor connected to a 3-phase supply, the speed vs. current curve for induction generator operation is like a mirror image of the speed vs. current curve for motor operation. That would mean that the maximum speed would need to be limited to the synchronous speed plus the full-load slip. The web site indicates that the full-load speed for the motor that they used is 1725 RPM for 3-phase operation. That would make the maximum speed 1875 RPM plus the additional slip due to the single phase with capacitor arrangement.
Is there a company that makes and sells wind turbines coupled with a hydrogen generator preferably in Europe?
I am trying to find out if there is a system (for sale) that delivers electricity from a wind turbine, and when there is no electric consumption another device creates hydrogen (through electrolysis). The hydrogen is stored and used later on for periods when there is not enough wind… The extra extra electricity can be “dumped” in the national grid after the tank is full. The system is for 2 3 houses max, there is enough space, and the area is suitable for wind turbines. Thanks.
The Neitherlands or Holland has something like that. (Just search the web)
Imho , I would go with solar. It’s more consistent and there’s a lot of guides and people to help you with them. Windmills require a lot more hardware and a very good location to be worth it.
There’s even ebay selling the cells you could use to build your own panels. Here’s a Squidoo lens where a guy explains how to assemble one, you might want to check it out. http://www.squidoo.com/solarpanelscheap
Hope it helps
Haven’t heard about it, but sounds like I would want one.