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A. After some guidance and clarifications from Teslagenx, I wired in a SPDT switch with the 8 transistor board and Charge battery connections. This results in a switchable charging mode. First mode is the normal SSG output configuration on the Charge battery. Selecting the 2nd mode connects the Charge battery in a common ground configuration and adds a diode in that side of the circuit..... as described in the Advanced Book.
Observations:
1.) Be sure to take out final assembly instruction connections in step 2-1 on 8 Transistor board assembly, before installing the wiring and SPDT switch.
2.) My wheel RPM decreased about 100 RPM when switched from SSG to Common Ground charging mode; 270 -> 170.
3.) Amp meter on Run Battery showed 0.5 increase draw.
4.) Charge voltage increases about 1 - 2 volts.
5.) Charge battery charges faster, which is a good trade-off for the small increase in running amperage.
B. I made the Low-Drag generator coil, following the recommendations in the Advanced book, with two modifications.
Observations:
1.) Added about 10 ft to each winding, to add a few more turns on the coil and compensate for wire shortening during the twisting process, for a total length of 140ft.
2.) Added 2 additional windings for a total of 12.
3.) Added an additional 1 inch to center core making it 2.5 inches wide. This is for future experiments to attain better performance.
4.) If you are twisting the coil wire without help, recommend you find a grassy area to layout wire so as not to scuff the thin coating. Then locate center of the wire's length and bend it around a small rod driven in the ground. Twist each half separately. While there may be a 1 -2 inch segment that is not tightly twisted, it can be hand twisted during the winding of the coil,to tighten that small wire length. If the wire is not sufficiently twisted, it will be bigger in diameter, which can affect how much get wrapped on the spool. The twisted wires made a very stiff cable.
5.) Winding the stiff, twisted wire is like winding solid copper metal. It is fatiguing to the wrists and fingers. It will require several sessions to complete.
6.) Connecting the individual windings in series is necessary to get the most voltage. requires a volt/continuity meter to locate the bottom end of each winding. Find some good wire connectors that will grip each cleaned wire end. With the help/experience of fellow-contributors Aaron Murakami and James McDonald, serializing the windings were successfully completed.
7.) Mounting the coil is important. Mount it as close to the wheel as possible to get the highest voltage. Rotate the wheel slowly to find the minimum distance where the highest magnet/wheel bobble will not touch the coil and add 1/16 inch gap.
8.) Mount it so it does not come loose, when the wheel is turning. I drilled a hole in the rods that extended below the coil and pinned it to an anchored cross member with a woodscrew.
9.) The output initial thru a bridge rectifier was disappointing; only 7 volts and 55 milliamps. With not enough wheel RPM (130 RPM with generator next to magnets) and lots of drag from the wide coil core, the performance was poor.
10.) To improve RPM, I reduced the gap on the power coil to about 1/16 inch and loosened the wheel bearings, adding and a film of STP (oil additive) to both bearings.
11.) Added a stack of 2 small Neo magnets super glued to each side of the rim, in between ceramic. Best voltage attained with South side facing out. They are far enough away from the coil core, facing slightly sideways. No adverse effects on the power coil were seen. While the power coil sees only a North magnetic field, the generator coil sees an alternating North field, then a South field across its wider core.
12.) Wheel speed without generator coil attached and running in SSG mode was 275 RPM.
13.) Wheel speed with generator attached is now 175.
14.) Voltage increased to 11.8 and current increased to 250 milliamps thru bridge rectifier. This accessory has potentially useful power now.......
15.) No generator testing to date in Common Ground mode.
Anyone getting better low-drag generator performance?? Any SSG self-running potential being explored with this surplus power??
I will be further tuning the generator output. Also planning to create a PMH-design generator, to see if the low-Lenzing character will improve the SSG Wheel speed and PMH generator output. See MrAngusWangus channel on You tube, for additional description/characteristics. More on that to come.
Observations:
1.) Be sure to take out final assembly instruction connections in step 2-1 on 8 Transistor board assembly, before installing the wiring and SPDT switch.
2.) My wheel RPM decreased about 100 RPM when switched from SSG to Common Ground charging mode; 270 -> 170.
3.) Amp meter on Run Battery showed 0.5 increase draw.
4.) Charge voltage increases about 1 - 2 volts.
5.) Charge battery charges faster, which is a good trade-off for the small increase in running amperage.
B. I made the Low-Drag generator coil, following the recommendations in the Advanced book, with two modifications.
Observations:
1.) Added about 10 ft to each winding, to add a few more turns on the coil and compensate for wire shortening during the twisting process, for a total length of 140ft.
2.) Added 2 additional windings for a total of 12.
3.) Added an additional 1 inch to center core making it 2.5 inches wide. This is for future experiments to attain better performance.
4.) If you are twisting the coil wire without help, recommend you find a grassy area to layout wire so as not to scuff the thin coating. Then locate center of the wire's length and bend it around a small rod driven in the ground. Twist each half separately. While there may be a 1 -2 inch segment that is not tightly twisted, it can be hand twisted during the winding of the coil,to tighten that small wire length. If the wire is not sufficiently twisted, it will be bigger in diameter, which can affect how much get wrapped on the spool. The twisted wires made a very stiff cable.
5.) Winding the stiff, twisted wire is like winding solid copper metal. It is fatiguing to the wrists and fingers. It will require several sessions to complete.
6.) Connecting the individual windings in series is necessary to get the most voltage. requires a volt/continuity meter to locate the bottom end of each winding. Find some good wire connectors that will grip each cleaned wire end. With the help/experience of fellow-contributors Aaron Murakami and James McDonald, serializing the windings were successfully completed.
7.) Mounting the coil is important. Mount it as close to the wheel as possible to get the highest voltage. Rotate the wheel slowly to find the minimum distance where the highest magnet/wheel bobble will not touch the coil and add 1/16 inch gap.
8.) Mount it so it does not come loose, when the wheel is turning. I drilled a hole in the rods that extended below the coil and pinned it to an anchored cross member with a woodscrew.
9.) The output initial thru a bridge rectifier was disappointing; only 7 volts and 55 milliamps. With not enough wheel RPM (130 RPM with generator next to magnets) and lots of drag from the wide coil core, the performance was poor.
10.) To improve RPM, I reduced the gap on the power coil to about 1/16 inch and loosened the wheel bearings, adding and a film of STP (oil additive) to both bearings.
11.) Added a stack of 2 small Neo magnets super glued to each side of the rim, in between ceramic. Best voltage attained with South side facing out. They are far enough away from the coil core, facing slightly sideways. No adverse effects on the power coil were seen. While the power coil sees only a North magnetic field, the generator coil sees an alternating North field, then a South field across its wider core.
12.) Wheel speed without generator coil attached and running in SSG mode was 275 RPM.
13.) Wheel speed with generator attached is now 175.
14.) Voltage increased to 11.8 and current increased to 250 milliamps thru bridge rectifier. This accessory has potentially useful power now.......
15.) No generator testing to date in Common Ground mode.
Anyone getting better low-drag generator performance?? Any SSG self-running potential being explored with this surplus power??
I will be further tuning the generator output. Also planning to create a PMH-design generator, to see if the low-Lenzing character will improve the SSG Wheel speed and PMH generator output. See MrAngusWangus channel on You tube, for additional description/characteristics. More on that to come.
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