Great video again, Manuel. I never done KN5L method on FT82-43, only on FT114-43 and FT140-43. I noticed that efficiency on single FT114-43 was 86-89% 28:4turns, but the same KN5L method on 2xFT114-43 was 92-93% on 80-15m and 89% on 10m band. I think it is worth trying stacked FT82-43.

Hello, the main measure is missing: the insertion loss! Assemble a second identical transformer and connect the two high impedance secondaries together. The primaries will go to the two ports of the VNA. Measure the transfer loss (Gain) and divide by two. Those who do not have a VNA can do the same test with an rtx, a power meter and a dummy load. Let us know. 73s.

The way this works, is that the primary winding needs to have enough turns to achieve an impedance of 150-200 ohms. This is why there is 2 turns on the typical FT240-43 and 3 turns on an FT140-43. A smaller core needs more turns. The more secondary turns, the more the high frequency response is adversely affected, with increasing stray L and components. So a trade off. The capacitor deals with stray inductance at the higher frequency end and is used to tune for best performance. It isn't necessary, but useful to tweak better performance. The other point is that binocular cores are naturally more efficient (this is why they are used in rf amplifiers and not toroids). I don't understand why toroids continue to have the focus of attention. Efficiency is improved by stacking - two FT140-43 are about 5-6% more efficient than a single FT140-43, only require a turn primary and therefore have a better HF response.

Merci Manuel! I’m anxious to see you measure the real losses at 5 watts. I am starting to think that the losses on the transfo for efhw are enormous, and nobody realizes it. Good work Manuel, Best!

Awesome video, thank you for the idea! I used a FT114-43 I am on a peak today with contacts Arizona to Florida. It works great!

I'm loving these! Thank you for sharing!!

That is something new to me hehe. In the notebook now for more experiments to make 😁. Thanks for sharing. 73

Excellent work winding the core, Manuel!👍 I know your fingers must have been approaching ‘cramp-threshold’ after all those previous attempts!👀 Mine would have been. Hope the TX results will be fruitful. These videos really give a boost to real-world QRP ops! 73

While I'm sure you can add sufficient capacitance by increasing the inter-winding capacitance this way, what I am curious about is any efficiency differences between the 2 different coil making methods, the bulk capacitor vs distributed capacitance. I have lots of capacitors on hand to use, but I'd like to use whichever method works best. Would you do an efficiency test for us in order to compare the 2 coils when you have an opportunity? Thanks.

Well, now to dig out my spare cores and . . . Thanks for the hints. 73 de W8IJN

Thanks for the video!

I have used your alternate whining method multiple times and it has worked very well. Is there an alternate winding for using it for traps for a multi-band antenna?

👍Thanks for sharing. Is that x5 15K parallel resistors (3K) load you have? I have made some UNUNs for EFHW where I ended up doing a similar thing to get a good match. In my case, I wound the primary turns over the secondary turns.

Thanks!

I think I'm feeling stupid at the moment. I've watched you wind that core at least five or six times now and it seems to me like you are winding up with effectively a 3:18 turn transformer. Winding the secondary the way that you are seems to me like the first 3 turns of the secondary are canceled out by the primary and subtracted and you wind up with a 3:18 Turn or 1:36 impedance ratio transformer instead of 3:21 and 1:49 respectively. What is the value of your load resistance. If you were figuring on 1:49 but only got 1:36 impedance ratio you might get an even lower SWR if you added three more turns to the secondary. Someone else mentioned stacking two 82-43 cores. That might be worth trying. Also have you tried 3:24 Turns ratio for 1:64 impedance ratio? TNX

Thanks for the video Manuel! I tested the KN5L windig after your hint as well this afternoon. And compared it with the "normal" 3to21 and 4to28 winding on a Würth core (similar size as a ft82). With the KN5L winding and 4to28 I got good results and even better with a 33pF capaciator. The würth core has a lower AL than the Amidon. I will test tomorrow also your Suggestionen of 3to21. But according AF7NX, there is maybe one general downside with this winding pattern. You will physically cross the low site (GND connection) wire with approx. 1/3 of the high site wire on the core. So this wires are very close and can have voltage difference of >210Vpp @10W and more. What do you think? 73 de Jan

Nice experiment, why is there only one connector (Antenna) ? There should be another connector for the receiver, right? How does this work?

This is really exciting - this week I bought ten of these toroids and 10M of that wire to experiment on. In another video you mentioned using an FT140-43 as the 1:49 UnUn for the 100W version of the U01. Have you tried this winding pattern on the bigger toroid? Cheers! -Rob VK4SSE

Could the ohmic loss in the primary be a reason for low efficiency when tested with 5W input? It's half the thickness of a traditional bifilar winding and will be carrying 7x the current of the secondary.

what value for your dummy load over antenna and earth terminal please ? the resistor ?

Can i do with 140/43 toroid? Thank's

Danke

I enjoy this series! vy 73 de Mike

Nice video. Please, AWG number? Thanks, Friend. 73 PU2AOO