rhythmodynamics | What will, or what should be the energy of the future? What natural phenomena and processes will be at its bottom line? At what level of matter organization should one look for these phenomena and processes? These questions increasingly trouble the scientists engaged in exploring the new sources of energy, new means of its production.
Traditional means of energy production, for example, electricity, are known for their use of kinetic energy obtained from the wind, heated steam or pressure of falling water. In the first and second cases, it’s pressure difference which causes propulsion force, in the third case – it’s the force of gravitation. To obtain pressure difference artificially one has to use energy, burn fossil or nuclear fuel at power plants. Hydroelectric power stations require no fuel of course, as they are using a natural force of propulsion. Let’s examine the origin of this force and assess a possibility of designing its artificial analogy.
Little is known of the nature of the force of gravitation applied to experimental bodies. Lots of hypotheses exist, but the question remains: what mechanism creates propulsion force causing bodies to fall? What exactly causes the body to react by its free fall?
Note: experimental body, a body whose potential is too small to disturb the outside field.
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If it’s the field which ‘catches’ body m and then ‘drags’ it toward the earth’s surface, what’s the mechanism of this?
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Could the field be exerting its influence on body m if the body stayed unaffected by the field’s presence? If body m is to react, then why?
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Is the cause of free fall entirely external, or there are some changes taking place inside the body?
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What is to change inside the body so as make it move?
Rhythmodynamics views bodies as systems of interacting synchronous elements (oscillating experimental bodies) situated in a wave medium, the medium which has a propensity to carry periodic disturbances and propagate them with constant speed.
All principles are examined in the case of the least possible elementary system (fig.1) made up of two oscillating elements linked together by the standing wave.
Fig.1. The system has no reason to move in the wave medium because positions of the sources-oscillators and potential holes (nodes) coincide. The system is internally balanced.
The standing wave, being a disturbed state of the medium, plays the role of a common platform for the elements. Although this platform is floating in the wave medium, it’s also rigid, because the system’s elements, engaged in exchange of the wave energy, create potential holes and thereby fix each other there at a set distance.
The elementary system coming under pressure of internal or external factors may develop phase or frequency displacements which break wave synchronism and upset the existing balance.
Balance [equilibrium], a state created by the forces of a different vector cancelled out so that the system’s properties remain unaffected.
Dynamic balance [dynamic equilibrium], a process in which the controlled system develops in such a way which prevents significant deviation of the system from the set trajectory caused by the medium disturbances.
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