Stanley Meyer WFC Scaling
Earl Was Mentioning
"using 6 cells instead of 10 he was working out math differences.
6 cell should change the R factor of cells and also L and C values.
Ronnie had shown all the calculation for 10 cells
and said it could be scaled but he never provided figures for 6 cells"
So I post this here for some deeper research this
was from several hrs of Ai re writes
Fundamental Scaling Relationships
The scaling calculations are based on well-established electrical engineering principles for parallel circuit configurations.
When cells are connected in parallel, the following relationships apply123:
Capacitance Scaling: Total capacitance increases linearly with cell count
Attached
Advanced Scaling Considerations
Non-Linear Effects
While the basic scaling relationships are linear, several non-linear effects become significant at high cell counts:
Skin Effect: At high frequencies, current concentrates near conductor surfaces, effectively increasing resistance
Proximity Effect: Magnetic fields from adjacent cells can affect inductance values
Thermal Runaway: Uneven heating can create positive feedback loops in large arrays
Optimization Strategies
Modular Approach: For very high cell counts (>200), consider multiple smaller modules rather than one large array
Active Balancing: Implement current monitoring and balancing circuits for large arrays
Thermal Management: Use thermal modeling to optimize cooling system design
This comprehensive scaling guide provides the mathematical foundation and practical guidance needed for successful Stanley Meyer WFC scaling across the complete range from 12 to 1200 cells, enabling builders to make informed decisions based on their skill level, available resources, and performance requirements.
Earl Was Mentioning
"using 6 cells instead of 10 he was working out math differences.
6 cell should change the R factor of cells and also L and C values.
Ronnie had shown all the calculation for 10 cells
and said it could be scaled but he never provided figures for 6 cells"
So I post this here for some deeper research this
was from several hrs of Ai re writes
Fundamental Scaling Relationships
The scaling calculations are based on well-established electrical engineering principles for parallel circuit configurations.
When cells are connected in parallel, the following relationships apply123:
Capacitance Scaling: Total capacitance increases linearly with cell count
Attached
Advanced Scaling Considerations
Non-Linear Effects
While the basic scaling relationships are linear, several non-linear effects become significant at high cell counts:
Skin Effect: At high frequencies, current concentrates near conductor surfaces, effectively increasing resistance
Proximity Effect: Magnetic fields from adjacent cells can affect inductance values
Thermal Runaway: Uneven heating can create positive feedback loops in large arrays
Optimization Strategies
Modular Approach: For very high cell counts (>200), consider multiple smaller modules rather than one large array
Active Balancing: Implement current monitoring and balancing circuits for large arrays
Thermal Management: Use thermal modeling to optimize cooling system design
This comprehensive scaling guide provides the mathematical foundation and practical guidance needed for successful Stanley Meyer WFC scaling across the complete range from 12 to 1200 cells, enabling builders to make informed decisions based on their skill level, available resources, and performance requirements.