Wind Turbine & Enphase IQ7 system integration success

To update the buck power supply trials, I now have a 30-96v power supply rated at 400W or so. It seems to be able to handle the turbine. We haven't had a big wind storm yet and I'll use it the next time there is one to see how it does in high winds. The turn on voltage is about 29.5v and the output voltage is about 22.9. So it's working and will give much better power output if windy enough. It allows the turbine to spin faster and produce more power. However, in my urban environment with trees and structures I don't get enough steady wind at a high enough velocity to make power consistently. So for low wind cases, you will actually produce less power than straight from the 48v turbine since when I'm observing the turbine its running in the low to mid-20v range which doesn't produce any power. I'm going to install a manual switch initially to be able to cut in the power supply if we have a good wind storm. Otherwise, I'll keep the turbine directly into the circuit without the power supply since that cut-in voltage is 16v or so. I may eventually have it automatically switched in by monitoring wind speed. But that's going to take me getting the anemometer up and running. I've modified it to have only one magnet on the hub and have to get it calibrated. Hopefully sometime this summer I'll have it mounted and running via a raspberry pi. I'll modify the above circuit diagram to include the buck power supply. I'm thinking I might install another turbine at a family home in Iowa where it's windy using this circuit. Then see the results. But that will be a ways off. In the meantime, I'll keep fine tuning my operation.

Here is a video of the power output of the turbine with a buck power supply added. This is one of the ones that smoked after about 5 minutes due to high input voltage (I think).

To update on the buck supply, it does work but in low winds the cut in voltage is too high to produce any power. The turbine has to get up to 29+ VDC before the supply kicks on. Lots of my wind is under that so I miss production. There is a guy on an Arduino programming site that has a wind turbine power converter that is boost and buck combined. It operates as low as 10v. The posts are 2-3 years old so I'm not sure if he still sells the boards.

But here is another design that may also be of interest:

Then also a UNT masters thesis on a combined solar and wind MPPT:

Will I build one? Maybe. The UNT provides the most code and might be the where I take from to do the mattgadient version. Right now I have a switch installed to manually toggle between the buck supply and direct from turbine to the IQ7. The UNT paper discusses cutting in higher loads as the wind speed increases. Something I might want to do. Light winds are forecast for the next two weeks which will limit my being able to test switching in the power supply during higher winds.

Pat

There has been a noticeable improvement in power production with the turbine lowered and the leaves off the trees. 650W of generation in the last month. WooHoo...(sarcasm :-) ) .

For those of you who keep asking what if you put batteries instead of the super capacitors in the circuit. Well, I've now got 4 spare AGM batteries so I'm going to put them across the DC side of the diode bridge and see where power production goes. I should have it hooked up by the end of December. I need to put a low voltage cutout in the circuit to make sure the microinverter doesn't kill the batteries. I'm going to leave the super caps in place as well as the switching power supply as my system is set to run below 26 volts. I've done some initial tests allowing the turbine to free spin up to over 40v then put it onto the circuit. It appears to produce more power, and it causes the switching power supply to run higher than 29.8v.

The purpose of the test is two fold:

Will the turbine produce more power with it running at design voltage? Most likely.

Will the microinverter operate properly when hooked up to battery power? I think so. And does the low voltage cutoff cause any problems? It shouldn't.

The rest of the circuitry must remain as the microinverter must be kept in at least standby mode and I need to avoid the unpleasant and funky non-production mode I've had trouble with if It doesn't start producing power at a nominal 23 vdc input.

So stay tuned and I'll update when its up and running.

And Have a Happy Holiday folks!

Pat

As expected, the IQ7 just pulls power from the batteries until the low voltage cutoff disconnects the batteries from the circuit. Stubbornly, there was no wind to speak of yesterday. Weathermen and their forecasts... Next opportunity is Tuesday. Got over 700W out of the stored energy in the batteries though.

Most likely the time delay relay and the 26v/20v low voltage cutout are not needed if you use batteries. The circuitry would also probably need to be tweaked to take into account a 48 volt operating level if you didn't use the switching power supply to drop the voltage down to 24v from the turbine. It would also require a change in the solar panels supplying the voltage bias during the daytime. The IQ7 gets clamped to the battery voltage negating any real MPPT action. This IQ7 is a 295W one. The buck power supply is not in the circuit contrary to my diagram above. A work in progress trying to figure out some glitch that's going on with it.

Pat

That will be an interesting experiment. If you haven't bought the Midnite yet, I'd test the isolation between a couple of IQ8s. They don't like to share a solar panel array with another MPPT controller, you get a ground fault error. I have not tried two IQ's in parallel yet. I just bought an IQ7 off ebay and will try that this week hopefully and see what happens. With a 2000W turbine, you're going to have to share the Midnite's output between IQs. I've tried to isolate with buck and boost power supplies but haven't been successful yet. Still trying to find a reasonably priced isolating power supply to test out. Your diagram doesn't isolate each IQ unless the voltage controllers are isolating. Most are not, especially most that are on AliExpress and Amazon.

You still need to realize that the hysteresis of the IQ's as they turn on will cause you issues with delayed turn on from off condition since you don't have a bias supply to keep them in standby mode.

That's an expensive setup. Hope you got lots of wind. :-)

And remember, the IQ8's output 240VAC not 120VAC. The enphase controller in your diagram is an encharge I'm guessing? Otherwise the design isn't quite right if its an Envoy controller. An Envoy only monitors and reports, it does nothing to the power generated.

Pat

Biggest issue you might have in the long run is making sure the turbine doesn't over produce, as in what if it's really windy and you get one or more IQx's fail/stop working. You'll need some kind of fail safe circuit to put the turbine power into a dump load. It gets complicated if you're using more than one IQx.

And you can get power out of the turbine below 41v. It just might not be power at the voltage level you need. The turbine produces power the minute it starts spinning. It's just most efficient at its' rated voltage. And at low speeds you are at low voltages. That's the problem with my circuit, it clamps the voltage of a 48v turbine down around 16.7v. So I don't get nearly the power output the turbine is capable of. A true MPPT controller for a wind turbine would be constantly adjusting it's output power based on the input voltage/current curve. Hopefully this MPPT board I'm populating is going to fix my problem and allow my turbine to operate where it's designed to.

pat