Copyright © Dr. Eng. Jan Pająk
Volume 2: Fundamental discoveries and inventions (ISBN 978-1-877458-82-8)
B. THE PERIODIC PRINCIPLE IN THE DEVELOPMENT OF PROPULSION SYSTEMS
B1. Everything in our environment, including the formulation of inventions, is governed by appropriate laws
B2. The basics of propulsion
B2.1. The working medium
B2.2. The primary requirement for building a controllable propulsion system
B3. Application of the Periodic Principle to propulsion systems
B4. The first generation of the magnetic propulsion systems
B5. How the "omnibus trend" should culminate in three conventions of the Magnocraft's operation
B6. Three successive generations of magnetic propulsion systems
Table B1 (The Cyclic Principle) - tables
C. THE MAGNOKRAFT
C1. The Magnokraft of the first generation - means my personal "Ariadna thread"
Figures C1a to C1c
D. THE FOUR-PROPULSOR SPACECRAFT
D1. The general design of the Four-Propulsor Spacecraft
D2. The operation of the Four-Propulsor Spacecraft
D3. The properties of the Four-Propulsor Spacecraft
D4. The external appearance of the Four-Propulsor Spacecraft
D5. Identification of the type of Four-Propulsor Spacecraft
Table D1 and 2 Figures (D1 and D2) - illustrations
[/url][url=http://wohin-woher.com/NV/showthread.php?tid=561]E. MAGNETIC PERSONAL PROPULSION
E1. The standard garment of personal propulsion
E2. Principles of operation of magnetic personal propulsion
E3. The garment with main propulsors in epaulettes
E4. A special version of personal propulsion with cushions around the hips
E5. Capabilities of personal propulsion
E6. Summary of the attributes of personal propulsion
4 Figures (E1 and E4) - illustrations
F. THE OSCILLATORY CHAMBER
F1. Why there is a necessity to replace electromagnets by Oscillatory Chambers
F2. History of the Oscillatory Chamber
F3. The principle of operation of the Oscillatory Chamber
F3.1. The electrical inertia of an inductor as the motive force for oscillations in a conventional oscillatory circuit with a spark gap
F3.2. In the modified oscillatory circuit with a spark gap, the inductance
of a stream of sparks replaces the electrical inertia of an inductor
F3.3. The combining of two modified circuits forms an "Oscillatory Chamber" producing a bipolar magnetic field
F3.4. Needle-shaped electrodes
F4. The future appearance of the Oscillatory Chamber
F4.1. Three generations of the Oscillatory Chambers
F5. Mathematical model of the Oscillatory Chamber
F5.1. Resistance of the Oscillatory Chamber
F5.2. Inductance of the Oscillatory Chamber
F5.3. Capacitance of the Oscillatory Chamber
F5.4. The "sparks' motivity factor" and its interpretation
F5.5. Condition for the oscillatory response
F5.6. The period of pulsation of the chamber's field
F6. How the Oscillatory Chamber eliminates the drawbacks of electromagnets
F6.1. Mutual neutralization of the two opposite electro-magnetic forces
F6.2. Independence of the magnetic field production from the continuity and efficiency of the energy supply
F6.3. Elimination of energy loss
F6.3.1. Premises for the recovery of all heat dissipated by sparks
F6.4. Releasing the structure of the chamber from the destructive action of electric potentials
F6.5. Amplifying control of the period of field pulsation
F7. Advantages of the Oscillatory Chamber over electromagnets
F7.1. Formation of the "twin-chamber capsule" able to control the output without altering the energy involved
F7.1.1. Twin-chamber capsules of the second and third generation
F7.1.2. The "ratio of packing" of oscillatory chambers and its influence on the appearance of twin-chamber capsules and spider configurations
F7.2. Formation of the "spider configuration"
F7.2.1. The prototype spider configuration of the first generation
F7.2.2. Spider configurations of the second generation
F7.2.3. Spider configurations of the third generation
F7.3. The non-attraction of ferromagnetic objects
F7.4. Multidimensional transformation of energy
F7.5. Continuous oscillating - a unique electromagnetic phenomenon allowing the Oscillatory Chamber to absorb unlimited amounts of energy
F7.6. Function as an enormously capacious accumulator of energy
F7.7. Simplicity of production F8. Advancements in the practical completion of the Oscillatory Chamber
F8. Advancements in the practical completion of the Oscillatory Chamber
F8.1. Experimental devices
F8.2. Stages, goals, and ways of their achieving in the experimental building of the Oscillatory Chamber
F8.3. An invitation to take part in the development of the Oscillatory Chamber
F9. Future applications of the Oscillatory Chamber
F10. Monographs describing the Oscillatory Chamber
F11. Symbols, notation, and units used in this chapter
FB. APPLICATIONS THE OSCILLATORY CHAMBER
FB1. Future applications of the Oscillatory Chamber as a battery for eco-cars
FB2. Senator McCain promised to award 300 millions dollars to the inventor of the energy accumulator that displays attributes of the Oscillatory Chamber
Table F1 and 13 Figures (F1 to F13) - illustrations
Volume 2: Fundamental discoveries and inventions (ISBN 978-1-877458-82-8)
B. THE PERIODIC PRINCIPLE IN THE DEVELOPMENT OF PROPULSION SYSTEMS
B1. Everything in our environment, including the formulation of inventions, is governed by appropriate laws
B2. The basics of propulsion
B2.1. The working medium
B2.2. The primary requirement for building a controllable propulsion system
B3. Application of the Periodic Principle to propulsion systems
B4. The first generation of the magnetic propulsion systems
B5. How the "omnibus trend" should culminate in three conventions of the Magnocraft's operation
B6. Three successive generations of magnetic propulsion systems
Table B1 (The Cyclic Principle) - tables
C. THE MAGNOKRAFT
C1. The Magnokraft of the first generation - means my personal "Ariadna thread"
Figures C1a to C1c
D. THE FOUR-PROPULSOR SPACECRAFT
D1. The general design of the Four-Propulsor Spacecraft
D2. The operation of the Four-Propulsor Spacecraft
D3. The properties of the Four-Propulsor Spacecraft
D4. The external appearance of the Four-Propulsor Spacecraft
D5. Identification of the type of Four-Propulsor Spacecraft
Table D1 and 2 Figures (D1 and D2) - illustrations
[/url][url=http://wohin-woher.com/NV/showthread.php?tid=561]E. MAGNETIC PERSONAL PROPULSION
E1. The standard garment of personal propulsion
E2. Principles of operation of magnetic personal propulsion
E3. The garment with main propulsors in epaulettes
E4. A special version of personal propulsion with cushions around the hips
E5. Capabilities of personal propulsion
E6. Summary of the attributes of personal propulsion
4 Figures (E1 and E4) - illustrations
F. THE OSCILLATORY CHAMBER
F1. Why there is a necessity to replace electromagnets by Oscillatory Chambers
F2. History of the Oscillatory Chamber
F3. The principle of operation of the Oscillatory Chamber
F3.1. The electrical inertia of an inductor as the motive force for oscillations in a conventional oscillatory circuit with a spark gap
F3.2. In the modified oscillatory circuit with a spark gap, the inductance
of a stream of sparks replaces the electrical inertia of an inductor
F3.3. The combining of two modified circuits forms an "Oscillatory Chamber" producing a bipolar magnetic field
F3.4. Needle-shaped electrodes
F4. The future appearance of the Oscillatory Chamber
F4.1. Three generations of the Oscillatory Chambers
F5. Mathematical model of the Oscillatory Chamber
F5.1. Resistance of the Oscillatory Chamber
F5.2. Inductance of the Oscillatory Chamber
F5.3. Capacitance of the Oscillatory Chamber
F5.4. The "sparks' motivity factor" and its interpretation
F5.5. Condition for the oscillatory response
F5.6. The period of pulsation of the chamber's field
F6. How the Oscillatory Chamber eliminates the drawbacks of electromagnets
F6.1. Mutual neutralization of the two opposite electro-magnetic forces
F6.2. Independence of the magnetic field production from the continuity and efficiency of the energy supply
F6.3. Elimination of energy loss
F6.3.1. Premises for the recovery of all heat dissipated by sparks
F6.4. Releasing the structure of the chamber from the destructive action of electric potentials
F6.5. Amplifying control of the period of field pulsation
F7. Advantages of the Oscillatory Chamber over electromagnets
F7.1. Formation of the "twin-chamber capsule" able to control the output without altering the energy involved
F7.1.1. Twin-chamber capsules of the second and third generation
F7.1.2. The "ratio of packing" of oscillatory chambers and its influence on the appearance of twin-chamber capsules and spider configurations
F7.2. Formation of the "spider configuration"
F7.2.1. The prototype spider configuration of the first generation
F7.2.2. Spider configurations of the second generation
F7.2.3. Spider configurations of the third generation
F7.3. The non-attraction of ferromagnetic objects
F7.4. Multidimensional transformation of energy
F7.5. Continuous oscillating - a unique electromagnetic phenomenon allowing the Oscillatory Chamber to absorb unlimited amounts of energy
F7.6. Function as an enormously capacious accumulator of energy
F7.7. Simplicity of production F8. Advancements in the practical completion of the Oscillatory Chamber
F8. Advancements in the practical completion of the Oscillatory Chamber
F8.1. Experimental devices
F8.2. Stages, goals, and ways of their achieving in the experimental building of the Oscillatory Chamber
F8.3. An invitation to take part in the development of the Oscillatory Chamber
F9. Future applications of the Oscillatory Chamber
F10. Monographs describing the Oscillatory Chamber
F11. Symbols, notation, and units used in this chapter
FB. APPLICATIONS THE OSCILLATORY CHAMBER
FB1. Future applications of the Oscillatory Chamber as a battery for eco-cars
FB2. Senator McCain promised to award 300 millions dollars to the inventor of the energy accumulator that displays attributes of the Oscillatory Chamber
Table F1 and 13 Figures (F1 to F13) - illustrations
