Another design proposal from Adriaan Kragten

Adriaan tells me:

“Recently I have written report KD 645 about the design of a new type 10-pole radial flux PM-generator with no iron in the coils and a simple 1-layer winding. This report can be copied for free from my website www.kdwindturbines.nl at the menu KD-reports.”

This is a ten pole design with 3-phase output using a standard motor body to enclose the working parts.  It’s great for keeping the magnets dry!  There is no iron in the stator which should mean it will be easy to start with no iron loss.  I suspect there will be some eddy current loss in the motor body (not shown in drawings) that encloses the coils.  Cooling of the coils will not be very effective though, which will place a limit on the continuous power output of the turbine.

The magnetic flux will be very weak and the actual performance (voltage per coil-turn per rpm) is yet to be determined.  Adriaan tells me “the costs of a PM-generator with an iron stator and about the same maximum torque level are much lower.”

I have no intention to build a prototype and test it but it would be good if someone else would test this idea. If the generated heat in aluminium is too high, one should use a housing made out of a synthetic material.”

PS: Adriaan further tells me he has designed a very small version “I have designed a 10-pole hub dynamo for a bicycle using the same principles as used for the 10-pole dynamo as described in KD 645. However, for the hub dynamo the rotating armature is at the outside and the stator with coils is at the inside. Although this dynamo is especially designed to be used in a bicycle, it might also be possible to use it in a very small wind turbine with a diameter of about 1 m. The idea is described in the note: “Ideas about an ideal hub dynamo” which can be found at my website: www.kdwindturbines.nl at the bottom of the menu “No wind energy”. There is also a Dutch version of this note which I have sent to a Dutch bicycle magazine to be published but I don’t know yet if they will accept the note or a summary of it.”

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A new alternator for my little AWP windmill

I don’t usually write much at all about the stuff I get up to, but here is a story of my smaller wind turbine having an upgrade last month when I replaced the alternator.  I was helped by my friend Jonathan Schrieber.

Let’s start with a photo of the African Windpower turbine I erected behind my house in 2007.  It’s a design I did for manufacture in Harare in 1996 or so.  Already here it has a Scoraig tail and Scoraig wooden blades.  It was connected to my 48V batteries.  There weren’t so many trees around in 2007 or they were small.

 

 

 

 

Here’s a picture of the wooden blades carved by my neighbour Michel Grenier.  The fibreglass ones from Africa work ok, but they tended to break a lot, which is why we needed to replace them.  Wooden ones seem to last longer.

 

Here’s a shot of the AWP alternator.  It’s built with ferrite magnets inside a cast iron “drum” and it has a laminated steel core.  It’s really heavy (70kg) and tends to overspeed in high winds due to the fact that the steel core limits its output current.  Nowadays I prefer the axial flux design and that’t what we made to replace this one when its stator insulation failed.

Hoisting it up on a 20 metre tower using a gin pole and Tirfor rope hoist.  Tower diameter is 89mm overall (3″ steel pipe) which is a bit slender and snaky.

From the rooftop of the house.


It hasn’t been without it’s dramas over the last ten years.  For example here is the result of a severe storm in 2015 when the shaft snapped and the rotating parts fell to the ground.  I decided not to run it so hard after that.  I’d been using a Midnite Classic to drive it a bit hard and get more power out of it.

By the time I had fixed everyone else’s windmills (quite a bit of damage in that storm, so it took six weeks) and took my one down, the shaft fracture had already rusted a bit.  Or maybe it had been cracking for a long time…?

Seen from the big windmill.

The AWP windmill ran nicely for 2 years or more after this fix, but some time in August this year I noticed it was running poorly and producing low power.  There is a data logger on it and you can even see what it is producing right now to the right of this column in the little chart.  The stator had an internal short that I was unable to remedy without a rewind.

Here is Jonathan winding the first coil for the axial flux replacement alternator following this year’s insulation failure.  Rewinding the older stator is extremely laborious and anyway I prefer axial flux nowadays so glad to move on to the newer design shown below.

 

We used 60 turns of 2-in-hand 1.4mm diameter wire.  The coils came out just right to fit 15 coils in the stator.  We put 20 ferrite magnets on each steel rotor disk.

I like to use stainless steel wire reinforcement around the magnets prior to casting them in resin.  This has stood the test of time.  I don’t use glass cloth with ferrites, because the magnet stand proud in the resin without covering.  They don’t need protection from anything, as they are extremely robust.  Not a corrosion time-bomb like NdFeB magnets!

A rotor in the mould ready for resin.  The handle makes it easier to lift into place.

 

Here’s the stator.  10.2kg weight. Over 7kg of that is copper.

The frame of the machine ready for building the alternator.

Mounting the back magnet rotor (24.5kg) onto the big trailer hub.

The whole assembled windmill hanging off a hoist, waiting for the wheelbarrow. Over 100kg.

We didn’t have time to do much to the old blades.  They were still in perfect balance when checked sitting on a spike at the exact centre.  Leading edges were in good shape so I guess I must have done them within the last five years.

Easing the machine onto the tower top.

The down-tower wiring strapped onto its supports ready for crimp connections to the stator tails. I use small bore copper pipe to crimp the wires after they are tightly twisted together within the pipe.

A quick coat of linseed oil on the rusty metalwork.

Fitting the blades. We added an extra piece of birch plywood for luck.

Ready for lift-off. The trees have grown a bit since 2017.

Up and running sweet and smooth. I made the tail telescopic but I don’t think I will need to adjust it. Governs out at about 1200W average power.

Magnets – 20 per rotor – 75x50x20 ferrite Y30BH C8

Coils 15 of them 60 turns of 2×1.4mm dia. wire 460g each.

Nominal cut-in for 48V DC is 134 rpm.  1200W rated output at 260 rpm

Blade diameter 3.6 metres

Rotor lateral offset for furling 200mm.

Tail hinge angle 15 degrees.  Tail moment of weight 29 kg-metres.

Vane area around one square metre of 9mm birch plywood.

 

Posted in construction, ferrite magnets, my own projects, Scoraig | 4 Comments

16 foot homebrew in Wyoming

“Hello again.

We are in wyoming, only 30 miles from proposed LARGEST wind farm in WORLD( cherry choke project ) best wind zone in USA here.  3000 new GIANT wind generators will be installed here in  next  year. 

7200 ft elevations. 40 below zero winters, 100 + plus winds here with out storm or bad weather.

We have tested your wind mill plans here, they have worked prefect for 4 years now.. so

We built  ONE 4 TIMES LARGER ( scale )  8ft blades, 16ft total spread, on chevy 5 ton truck front axle 15K lbs weight rated bearings.

Does 85 amps @ 12 mph winds with NO resitor. 

here are some pics.. 

one pic shows it next to your standard one we built, 4 years ago.

Only problem we have now is TOO much power, new challenge is where to divert all this extra power. 

thanks

Mac”

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Free workshop in Austria

It probably helps to speak some German.

 free participation in a do-It-yourself Windmill Workshop! Take advantage of the special chance!   the workshop will be soon, from 7. To 11. August in the sun park st. Pölten in the framework of the eschmiede summer workshops. It is fully supported and therefore free (you save about 300 € per person). There are only 14 places, so register quickly!

Registration at: https://www.eschmiede.at/event/windrad-selbstbau-workshop/

More information at: http://pureselfmade.com/wind-turbine-workshops/

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Axial flux alternators overheating

I got this question by email and I thought it worth answering it publicly.

Hugh, It seems home made axial flux pma’s are prone to overheating at fairly low speeds compared to conventional gas powered generators that run at 1,800 rpms or more. If so what’s the cause and how can they made to prevent overheating?  Thanks Alan, Idaho, US

Hi alan,

All generators will produce waste heat, and this can cause overheating if overloaded.

Low speed generators have a handicap which means their power to weight ratio is much lower so they are usually low power or very heavy. Higher rpm allows for a lighter and/or more efficient design but we need a low speed generator for direct-drive operation by large diameter blades.

Axial flux alternators are a good choice for small wind turbines because they are easy to build and have very low parasitic losses (magnetic drag and suchlike), meaning they are very efficient at part-load, but they do become inefficient on full load, and will ultimately overheat on overload.

When using any alternator it is important to know its limits and to design the turbine so that it will not be overloaded.  Unfortunately the book published by Otherpower does suggest that you can push a very small alternator up to 1000 W output at low rpm and this has lead to a lot of burned stators in the USA.  Burned stators are more or less unknown to me using my recipes because I make sure that the furling system works to protect the alternator from overload.

Building a big enough alternator is the best way to avoid overheating.  And protecting it against overload.  Using MPPT controllers and inverters can increase the power output available in strong winds by raising the operating voltage but this is costly.  Often the power obtained in stronger winds is of less value since the batteries are already charged at this point.

I hope this helps!  I am putting this on my blog as it is a good question to ask.

cheers

Hugh

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Grid-tied 2F windmill self-construction project with Jonathan in Austria

Small wind turbine Do-It-Yourself Workshop incl. Installation

Windmill type:  2F 16p piggott (2m rotor, grid feeding)
Location:  FH Technikum / Energieforschungspark Lichtenegg
Participants:  15 people
Country:  Austria
Date:  Spring 2017

The machine is currently under test alongside some larger ones and doing well.

For an ebook with details of how to build the 2F click here.

read more (in German) here

Posted in construction, courses, ferrite magnets | 1 Comment

Build a Small Wind Turbine with Kostas Latoufis in Portugal August

One Week Course:

Build a Small Wind Turbine with Kostas Latoufis

August 21 to 27 2017, Montemor-o-Novo, Alentejo, Portugal

The wind turbines built in the workshops are based on the designs of Hugh Piggott, a renewable energy expert living in the off-grid community of Scoraig (Scotland), as described in his ‘Wind Turbine Recipe Book’. These wind turbines can be constructed with the use of common materials, simple manufacturing techniques and basic tools, providing a low cost small wind turbine that anyone can built. Hundreds of homemade small wind turbines have been constructed worldwide using these designs, and have proven to be robust, efficient, easy to maintain and quick to repair. Typical applications of locally manufactured small wind turbines are development projects such as electrification of village communities in the global south, educational projects in universities and schools and sustainability projects such as renewable energy electrification of ecovillages. ‘Nea Guinea’ has been organizing small wind turbine construction workshops since 2009 and has empowered many people with the knowledge of harnessing power from the wind.

 

Course Program

During this one week course a 600W small wind turbine with 2.4m rotor diameter will be constructed from scratch, using simple raw materials like wood for the blades, steel for the mounting frame and tail, copper wire for the coils and neodymium magnets cast in resin for the generator. The wind turbine will be the product of enthusiastic team work, as we will work in groups focusing on woodworking, metalworking and generator fabrication, along with short breaks to share what we have learned with the whole team. Woodworking will involve hand curving the blades of the rotor using drawknives and spokeshaves, planes and chisels. Metalworking will involve fabricating the steel frame to support the generator, blades and tail, with the use of welding, grinding and drilling techniques. Generator fabrication will involve winding coils, placing magnets, preparing plywood moulds and casting the stator coils and rotor magnet disks into resin. Basic woodworking and metal working skills will be taught during the course, and will enable all participants with enough hands-on experience to complete the wind turbine construction.

The course will be led in English by Kostas Latoufis. Kostas has been active in the off-grid renewable energy sector for 10 years. After completing his electrical and electronic engineering degree at the Imperial College of London (UK) in 2000, he traveled to Central America and South East Asia while also training as a silversmith. In 2004 he started working as a renewable energy researcher in the Smart Grids Research Unit (SmartRUE) of the National Technical University of Athens (NTUA). He started constructing Hugh Piggott small wind turbines in 2007 with the F.A.R.M.A. collective and continued with educational construction courses for students, in the Rural Electrification Research Group (RurERG) of the NTUA. In 2009, he co-founded the Nea Guinea not-for-profit organization, with which he has organized many small wind turbine construction courses, building windmills with rotor diameters from 1.2m to 4.2m, and many solar panel and pico-hydro construction courses. While working with Nea Guinea, he has carried out several off-grid renewable energy installations in permaculture farms in Greece and in rural development projects in Central America and East Africa. He is currently a member of the executive board of the Wind Empowerment association, a global network for the promotion of locally manufactured small wind turbines, and he is also pursuing a PhD in the NTUA on the same topic.

 

Detailed Program

Day 1

– Arrivals during the morning and introduction of participants

– Workshop activities (woodworking, metalworking, generator fabrication)

– Introduction to off-grid renewable energy systems (solar panels, solar pumps, wind turbines, hydro turbines)

Day 2

– Workshop activities (woodworking, metalworking, generator fabrication)

– Dinner and evening break

– Introduction to small wind turbine basics (wind energy, aerodynamics and blades)

Day 3

– Workshop activities (woodworking, metalworking, generator fabrication)

– Dinner and evening break

– Introduction to small wind turbine basics (electromagnetism and generators)

Day 4

– Workshop activities (woodworking, metalworking, generator fabrication)

– Dinner and evening break

– Introduction to small wind turbine basics (furling tail system and tower installation)

Day 5

– Workshop activities (woodworking, metalworking, generator fabrication)

– Dinner and evening break

– Introduction to small wind turbine basics (electrical system and battery connection)

Day 6

– Workshop activities (woodworking, metalworking, generator fabrication)

– Dinner and evening break

Day 7

– Workshop activities (woodworking, metalworking, generator fabrication)

– Departures during the evening

 

 

General Information:

When: 21 to 27 August 2017

 Where: Oficinas do Convento, Montemor-o-Novo, Alentejo, Portugal

Maximum participants: 17 persons

Prices:

Until 15 July: Full course: 250€ – Full Course + Accommodation + Meals: 320€

After 15 July: Full course: 300€  – Full Course + Accommodation + Meals: 370€

Accommodation and Meals: Oficinas do Convento have space for 15 people accomodations in a common space. Theres also the possibility of camping. Breakfast, lunch and diner are are included.

 FB event: https://www.facebook.com/events/161527967716247/?ref=br_rs

 

Organization:

 Nea Guinea: neaguinea.org/english

 Cooperativa Integral Minga: mingamontemor.pt

 Oficinas do Convento: oficinasdoconvento.com

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TALLER DE FABRICACIÓN DE AEROGENERADORES Argentina

TALLER DE FABRICACIÓN DE AEROGENERADORES / CÓRDOBA 2017

Evento que se celebrará a la hora, en la fecha y ubicación siguientes:

Sábado, 24 de junio de 2017 a las 09:00

– hasta –

Domingo, 25 de junio de 2017 a las 18:00 (ART)

Maestro M. Lopez esquina Cruz Roja, AVEIT, Córdoba capital

Maestro M. Lopez esquina Cruz Roja

Argentina

Ver mapa

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Arduino based PWM diversion control system

I am a bit fanatical about using surplus energy from wind and solar systems.  I just had an article published in Home Power magazine about this subject.

I like using Tristar controllers in diversion mode and then triggering more usable diversion (AC water heating) from that using my Tristar Follower idea.  That’s my latest trick anyway and I am proud of it.  It’s done using hard-wired analog electronics.

However it turns out that there are folk out there who like things a lot more complicated, and I must say it looks like quite a lot of fun too.   Will Eert wrote to me to tell me about his Arduino based PWM diversion control system that talks to his Midnite Classic controllers and uses surplus solar energy to heat his water tank based so as to limit maximum current into the battery, and limit its voltage to the prevailing charging setpoint.

You can learn a lot more about Will’s project on the Midnite discussion forum here.

Here is a basic summary of what it does:

  1. The control uses a series of PID controllers to divert under various conditions. This means it modulates diversion at a variable rate based on the amount of power available. The control normally turns on when there 10w available of excess power anywhere in the system.

  2. The control has a dynamic high amp limiter which uses the WBJr amps for an limit amp signal. This lets me “over array” the battery bank but not worry about putting too many amps into the the battery bank (when conditions permit) while still being able to utilize the full output capacity of the array at all times.

  3. The control diverts power based on high amp flow to the batteries. This lets the control divert in Bulk if the excess power is available. I adjust this set point 5 amps lower than the dynamic amp limiter. At present I only divert into one HWT element which is two KW in size. If the amp diversion is at maximum then the amps to the battery increase and the dynamic amp limiter limits array output.

  4. The control also diverts power based on voltage. It always maintains the batteries within .3V of the battery charge setpoints. The divert setpoints are set .3V lower than the Classic charge setpoints. When the divert setpoint is exceeded diversion starts automatically. It is possible to be amp and voltage diverting while dynamically amp limiting at the same time.

  5. The control reads the Classic setpoints and adjusts its setpoints to match. This means that once the control is setup all the owner needs to do is adjust their Classic as they desire. The diversion control will make all needed adjustments to its setpoints to ensure diversion continues to happen optimally.

  6. The control diverts at 10HZ. This is tunable however this frequency keeps the inverter very happy.

  7. If the HWT tank thermostat opens the PIDs turn off and the Classic limits array output. Fully automatic.

Thanks for documenting all of this, Will!  I love it.

Posted in construction, Diversion load control | 4 Comments

More free designs at kdwindturbines.nl

Adriaan Kragten writes:

Dear Hugh

Recently I have developed two new small VIRYA wind turbines with axial flux generators, the VIRYA-1.25AF and the VIRYA-1.81. The design reports and the drawings can be copied for free from my website: www.kdwindturbines.nl.  A folder in which all seven free VIRYA designs are described, can be found at the menu “VIRYA-folders”. The main specifications of all seven free VIRYA designs are given at page 3 of the folder “Extended specifications VIRYA windmills”.

The calculations and the drawings of the VIRYA.1.25AF are given in report KD 626. The 8-pole generator of this wind turbine makes use of the front wheel hub of a mountain bike. The rotor is mounted to the front flange and the armature sheet is mounted to the back flange. An assembly drawing of the rotor and the generator is given in figure 1 of KD 626. Detailed drawings of the rotor and the stator sheet of the generator are given in the end of KD 626. The remaining drawings of the generator are given in report KD 608 of the VIRYA-1. The remaining drawings of the head are given in the manual of the VIRYA-1.36. The VIRYA-1.25AF is a rather simple design but has an acceptable Pel-V curve for 12 V battery charging.

The calculations of the VIRYA-1.81 are given in report KD 631. An assembly drawing of the rotor and the generator is given in figure 2 of KD 631. Detailed drawings of the rotor and the generator are given in a separate manual. The free manuals are given at the bottom of the list with KD-reports. The 8-pole VIRYA-1.81 generator has only one steel armature sheet with circular magnets glued to the back side. It has a synthetic stator sheet and synthetic coil cores and therefore no eddy currents are generated. As this construction results in a rather long way for the magnetic field flowing through air, rather strong and thick magnets have to be used. But as the magnets can be ordered at a rather cheap Polish company, the magnet costs are still acceptable in relation to the other costs which have to be made to build the VIRYA-1.81.

Yours sincerely

Adriaan Kragten

I cannot say whether these are good designs or not, but they are free, and Adriaan has done some proof-of-concept testing to find the best turns/coil and support the conclusions.  If you build a turbine according to any of these designs then I am sure he would love to hear about it.  He says “I am 70 years old now and I still like it to design things but I no longer feel the need to build what I have designed.”

I (Hugh) am not very comfortable with using a steel disk backing the stator, because of the losses in that disk and the thrust load on the bearings, but Adriaan is confident that these are both quite acceptable.

Adriaan’s work is very strong on detail, and theoretical analysis, which can be very helpful especially to students of small wind turbine design.  For example this diagram showing the matching of the alternator (Pmech) to the blades best tip speed ratio is especially helpful.

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