DE102014005273A1 - Inertia Drive, Inertia Technology - Google Patents

Abstract

Inertia technology means to gain kinetic energy and transfer it to a spaceship or other in order to slow it down, accelerate or influence it. The kinetic energy is obtained by accelerating an object of a mass in order to transfer the gained kinetic energy of the mass through a braking chamber, a buffer, a safety net, a magnet or other to the spaceship or other things. The energies of movement in space add up to a higher speed than the previous speed, as long as the mass that has been accelerated can influence the spaceship or other things, i.e. is not too light in proportion. Of course, slowing down and changing the position of the ship or other things are also possible. Three basic models, the "Inertia models" are shown on a separate sheet, these are also explained in "The description of the Inertia technology and the three basic models".

Description

The description of the Inertia technology and the three basic models

Via optical drive?

Description:

Inertia technology provides the ability to accelerate a spacecraft to any speed by extracting kinetic energy and delivering it to the spacecraft.

By an explosion, by the addition of compressed air or by a catapult a weight is accelerated and passes the following kinetic energy to a spaceship.

Basic idea:

To accelerate a spaceship to above-light speed requires more drive power than simple explosions, normal drives (engines, rocket engines, and other propulsion / thrusters), or nozzles. So, the idea is, how do you overcome this natural speed limit? and the fact that there is very little gravity and friction in space. It is easy to understand that drives generate kinetic energy, which is their main task. The Inertia technology produces kinetic energy and transfers it to a spaceship (or space station or other).

Functionality:

In a spaceship, an Inertia Drive is installed and produces kinetic energy, which is transmitted to the spaceship following. Here, the existing kinetic energy of the spaceship (the speed) plus the newly generated kinetic energy, the resulting speed or the kinetic energy generated is used as a braking force.

problem:

Does the kinetic energy generated affect a mass in space, the spacecraft itself? Are opposing forces possible because the spaceship behaves as a mass?

Is the interior of the spaceship a separate space in the sense of free-floating objects or crew, or is it influenced by new motive energies?

Description of the three basic models (sketches are attached, Inertia models):

Model 1. Anchor:

Is a test model to test the functioning in orbit of the earth or in the space station.

Into a can (or syringe) air (compressed air), gas or fuel is injected into the combustion chamber to move the weight, called anchor in this model. If fuel is introduced, it must be exploded. The kinetic energy of the anchor is transferred by impact or by the compression of gas on the can (the syringe). The can (the syringe) should be cordless and now move in the direction of the generated kinetic energy of the anchor.

A test is also possible on earth.

Model 2. Impulse:

Is a "pulse drive". A weight is set in motion and transfers the kinetic energy gained to the spaceship. The drive is firmly connected to the spaceship.

Air, gas or fuel is injected into the combustion chamber and is supposed to set the weight (buffer or buffer) in motion; in the case of fuel injection, it must be exploded. The kinetic energy of the weight (buffer or buffer) is transmitted to the spaceship through a brake chamber filled with gas or air, or magnetic properties to stop the weight. By the gas or air in the brake chamber, the weight is moved to the starting position, or by other technical solutions such as thread or supply of air or gas, or other. The pulse can then be executed again.

Model 3. Inertia:

Is the optimized type of the second model. In a tube, a mass (a ball, a weight, buffer or buffer) is accelerated by a catapult, by compressed air or by an explosion, or else accelerated by the resulting kinetic energy through a brake chamber (as described in the second model or through brake shoes) Constriction or through a stopper, or other) to the ship. The weight that passed through the track is brought by a return again in position for the kinetic energy recovery or stored there in the waiting position. Several weights can be installed in this Inertia model.

Remarks:

It is also possible to carry the weight (the mass) on a type of string (leash, chain, magnetic or through a safety net) and (by brakes attached to the string) to transfer the kinetic energy gained to the ship.

The weight (the ball, the anchor, the buffer or buffer) must have a relation to the moving mass, ie the spaceship or the space station or other, which affects the spaceship (the moving mass)!

Other but hardly significant methods are, for example, to use an engine in a closed space to gain kinetic energy and to transfer this following to an object (the spaceship or other), the engine itself is the mass which gives its kinetic energy.

Or to move a vehicle very slowly, or just to move it, and then transfer the kinetic energy to the spaceship or other.

Remarks:

The direction of movement is given by the model of the drive. The acceleration can be chosen freely. The drive can be swiveled, rotated and installed in any position. It does not necessarily exhaust gases, which can become a death trap in space, when they are cooled.

Note:

With too much gravity, the Inertia drive may not be strong enough to keep the spacecraft or other in orbit. Normal rocket engines, control nozzles, or drives are so necessary! The inertia should perhaps be used only at a higher speed, as long as energy (fuel) can be saved.

LIST OF REFERENCE NUMBERS

1

Is for the extraction and following for the transfer of kinetic energy in the form of a weight, as ball (ball), anchor (dumbbell) or as buffer / buffer (weight), installed.

2

Absorbs the kinetic energy of 1 , and transmits them to the ship, in the form of a magnet, a gas chamber or through a stopper, or other.

3

The combustion chamber or the catapult gains the kinetic energy for 1 , by combustion (explosion), by pressure (eg compressed air) or by catapulting, or else.

4

The feeder or catapult. As catapult as under 3 , describe, and as a supply for air, gas or fuel, or otherwise.

5

The inlet or outlet for (brake) gas, air or compressed air, or other.

6

The runway for the next handover of the kinetic energy of 1 , at 2 ..

7

The return of 1 , to 4 ..

Claims (4)

Inertia technology and its ability to gain and use kinetic energy, characterized by accelerating a body (mass) to transmit its kinetic energy through a brake chamber (a braking device) on a spaceship or other. Also, the reuse of the idea by double or multiple sequence or modification of the words used. The model anchor (model anchor) characterized by the simple transfer of the kinetic energy gained. The model impulse (model impulse) characterized by the transfer of the obtained kinetic energy and the return of the buffer or buffer (the accelerated mass) to the starting position. The model Inertia (model Inertia) characterized by the transfer of the gained kinetic energy, the return of the ball (buffer or buffer, or the accelerated mass) to the starting position and that multiple balls (multiple buffers or buffers) can be used or installed or used ,

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