The present invention relates to a fluid distribution system without resorting to the use of conventional piping system.
Since the late 19th century, the state of technology reveals that the piping system fluid is today made up of household pipes on an industrial scale.
This system has many drawbacks: the risk of contamination of fluids and environmental destruction, high cost production facilities and distribution, flow distribution greatly reduced, including the time taken by this distribution.
The present invention aims to overcome these drawbacks, because it presents a new system for distributing fluids at long distances, without using the current system of conducting water, gas, oil or other fluid through pipes.
In fact, the new system can propel the fluids in a gaseous state, through the space, to the receiver, which converts them into liquid. Thus, it allows, for example, to refuel aircrafts in flight, military gear fighting far from their base and to distribute water to several water towers.
The new fluid distribution system is made up of (3) facilities, namely, the preparation facility, the fluidic emission facility and the reception facility.
The implementation of the invention is understood through the following description with reference to the figures in the appendices” It is by no means exhaustive.
The preparation facility (
The fluid emission facility (
An irradiation tube (24) is coupled to the light sensitive plate (23) by one end and connected to the servomechanism (25) by the other end (b). The servomechanism (25) contains two side-mirror plates (26a and 26b) in the center of which is a zinc alloy and liquefied metalloid (19) in which is inhibited a crystal gem that supplies energy through the discharge pipe (12)”.
At the level of laterally placed mirrors (26a and 26b), the mirror (a) is close to a cold water pump (21) which consists to expel the air which is located in the servomechanism (25); and another pump (22) fixed to the mirror (b) draws air and cold water for purifying servomechanism”. And cold water exits as hot water at the level of mirror. (b).
The reception facility (
A quantity of a liquid is poured into the preparation tank (1) and heated to gasification. The obtained gas is brought the regulator (5) which reduces its speed and imposes a new speed by means of an ionic catalyst composed of liquid hydrogen. Thereafter, the gas is conducted to the evacuator (7) after which there is a valve (8) closed.
While the valve (8) is closed, the fluids emission facility (
The resulting energy is automatically transmitted via the photosensitive plate (23) and takes the path of the irradiator tube (24) leading to another zinc alloy capsule (19) and a liquefied metalloid in the presence of a rock crystal and this causes an energy that is propelled through the evacuator tube (12).
The energy fission in contact with the prism (28) of the divergent lens (18) creates an energy corridor (A) through the gap for a given time.
Once the valve (8) open, the gas is discharged to the emission facility (
The Independent boron plate (30) plays a role of energy sensor from the emission facility (
Once the valve (31) of the reception facility (
A black box (17) containing a prism (28) (
The front opening (15) has a divergent lens (18) which serves to direct the energy from the zinc alloy and a liquefied metalloid in the presence of a gem crystal, which passes through the means of a plate of chloride silver (20) prior to propel into space by the energy corridors, such as the corridor (A). This energy at the lens (18) is divided into several small bundles after undergoing light decomposition at the prism (28) level.
Thus, small beams take different colors. The number of created beams corresponds to the number of energy corridors and the number of reception facilities.
Reception facilities consist of a monochromatic frequency received by another prism (40) which allows to recognize the frequency emitted relevant to the characteristics/features of each beam.
Indeed, the gas from the evacuator tuber (12) prior to propel, encounters a stationary state magnetic field at the end of spillway/exhaust pipe (12) which splits the number of beams that thereof result. Thus, the gases are routed through energy corridors available to them.
To create seven (7) beams in the case of fluids emission to multiple reception facilities, it takes 70 grams of prism at emission/one (1) gram of prism at reception and 10 liters of zinc alloy and metalloid in the presence of one (1) gram of crystal gem, and a commercial lens of 0.4, including a 2 mm thick thin chloride silver plate (20) for maintaining energy for a 72 hour-period.
The merit of the new system is the fact that the fluids transmission is done, not by the use of current pipe supports, but by a distribution over long distances through space by an energy corridor. Besides the fluids transmission, the same system can serve for waves transmission to several reception facilities.
The materials used to create the different facilities of the system are among others metal, resin, wood and plastic.
Number | Date | Country | |
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62534242 | Jul 2017 | US |