Hi everybody, as a serius Stanley Meyer researcher I found this new release from Valentin Petkov as a staggering contribution in order to success building a working prototype. I had bad experiencies with some prototypes from Petkov that doesn't work as claimed but this one is maybe the one that we were waiting for. The cicuit diagram is a small scale replication from Stephen Meyer's circuit from patent US20050246059A1. Please, if you replicate Petkov's circuit please share your results and conclusions!
Here the link of his video:

https://www.youtube.com/watch?v=XRgnWxAHxWA
"Water Resonance High-efficiency Electrolysis - DEMONSTRATION" Released in March 21- 2020

Preserving external images as attachments.

God Bless Petlov 

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Dan
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Attached Description from his video

Petlov Circuit diagram:
https://drive.google.com/file/d/19mJjmEcAoya-kAw7tpWpuMbwv-A5lRpM/view

Jean-Louis Naudin attempt replication of Charge/Discharge signal, using "adhesive plastic sheet so has to get a fully insulated cathod":
https://drive.google.com/file/d/15wKgOWp28TWaTtSRv7VbA792lTL_eRD7/view

There is an errors in the Stephen Meyer`s circuit diagram! Here is the right circuit:
https://drive.google.com/file/d/1qvXyAmR199Lsdn6bygaO-Xe6DsyL7Hd8/view

Stephen Meyer vs. Stanley Meyer - differences
https://drive.google.com/file/d/1IsnMEq2XQ6ZT_F-KZyq9ip77LTbyEN5Y/view

Stephen Meyer`s Patent US 2005/0246059 A1:
https://patents.google.com/patent/US20050246059

Andrija Puharich`s Patent US4394230A:
https://patents.google.com/patent/US4394230

Stanley Meyer's US4936961A:
https://patents.google.com/patent/US4936961

Stanley Meyer's WO 92/07861:
http://www.rexresearch.com/meyerhy/wo92.htm

Drawing FIG. 5 shows the signals applied to each of the arrays 132 FIG. 3 installed in hydroxyl cell 120 emitted from each of the impedance matching circuits 102 FIG. 4 mounted on PC cards 1-6. These sets of signals FIG. 5 with their offsetting phase relationship, frequencies and amplitudes are the driving forces producing the hydroxyl gases in cell 120 FIG. 3.

Drawing FIG. 6 shows the high frequency ringing signal located between test points T1 and T2 in impedance matching circuit 102 drawing FIG. 4. It is this ringing that also enhances the production of the hydroxyl gases in cell 120 FIG. 3.

The circuits 102 FIG. 4 convert the AC signal from each phase of 110 into a modulated signal as depicted by FIG. 5.

Note the dc bias voltage +,− on either side of the center electrical reference point OV in FIG. 5. It is this bias voltage being modulated by multi polarity differential signals from 102 FIG. 4 that contributes to the wave-guide action of arrays 132. Also, the frequency of FIG. 5 is adjusted to match the electrical wave-length of the arrays 132 FIG. 3 and the impedance of water bath 133.

FIG. 6 shows the high-frequency ringing signals that contribute to the operation of the hydroxyl production. Just as a tuning fork rings when struck by a hammer, so does the wave-guide elements in arrays 132 immersed into the hydroxyl generating liquid 133 then struck by the electrical signals FIG. 5,6 from impedance matching circuits 102 depicted in FIG. 4.

The result of this is just like the operation of a radio transmitter matching its signal to the air via the antenna impedance. Refer to FIG. 3 showing the relationship of this configuration to arrays 132, water bath 133 and Signals FIG. 5,6.