DE4114910A1 - Drive unit for space vehicle - has double catapult for discharging equal masses in direction of opposing bases of drive housing - Google Patents

Abstract

The drive unit has a catapult housing within which 2 masses (M1, M2) are moved in the direction of the housing base, to provide an electromagnetic attraction and/or repulsion force. Pref. the drive unit has a double catapult system, with the 2 masses (M1, M2) each moved in the direction of one or other housing base (161, 162), with a periodic repetitive movement of the masses (M1, M2) which are pref. displaced at the same velocity. One of the masses (M1) has 2 identical halves, each having an electromagnet and an integrated energy source. The other mass (M2) formed by a single element. ADVANTAGE - Applicable for long-term operation of drive.

Description

The present invention relates to a drive device for itself moving vehicles, in particular for air and space vehicles.

In the previously known spacecraft, rockets are used as propulsion systems turns. Here, the spacecraft is given a boost that Mass is expelled through a nozzle at high speed.

In contrast to the rocket engine, which can only be used for a short time, can Drives in the design shown over any length of time space can be used.

The principle is also applicable to other areas of natural science from Be interpretation and explanation of relationships that could not previously be explained.

It shows:

Figure 1a shows a section through the device according to the invention with catapult housing and 2 masses.

FIG. 1b is an illustration of gem. Fig. 1 with speed components.

Description of Fig. 1a General

FIG. 1a shows a schematic illustration of two masses 151 and 152 of equal size, which are flung out of a catapult holder 153 , which is firmly connected to a housing 154 . After leaving the catapult, the two masses 151 and 152 should then have the same but opposite speed, and the mass 151 should at times be additionally under the action of an electromagnetic field, so that after the mass-energy equivalence, the mass 151 is smaller by the amount Δ m becomes.

Part of the device is a housing 154 with lower and upper covers 161 and 162 . The device is therefore completely self-contained.

When the mass 151 hits simultaneously, which has become smaller by the amount .DELTA.m due to the electromagnetic interaction and the mass 152 , which has retained its original mass, a resulting pulse A results at the same impact speed.

The experiment carried out as a thought experiment proves that the impulse theorem cannot have general validity. The attempt is on earth and in Space conceivable.

With the masses ( 151- Δm) and 152 , which are considered to be moving bodies, movement size is also transmitted. According to the set of impulses, the amount of movement is transferred to the body when the masses hit the floors 161 and 162 z. B. remain electromagnetic.

construction

The two masses 151 and 152 initially have the same masses in the catapult and have the same structure.

The mass 151 (also referred to as m 1 ) consists of two halves of the same size, in each of which an electromagnet and an integrated energy source are arranged. The mass m 2 could consist of a single part, but is preferably configured similarly to the mass m 1 .

The focal points of the partial masses 155 and 156 lie in their geometric center. Their common focus is on their lines of contact, which are marked with dashed lines. The paths on which the common centers of gravity should move are identified by the dashed lines 157 and 158 in the housing of the device, it being noted that the common center of gravity (also in the case of the trajectory curves 163 ) is the dash-dotted line 157 .

The magnetic pole axis 164 , which is intended to run in each of the electromagnets from the positive pole to the inus pole, should always lie parallel to the movement lines 157 or 158 of the center of gravity 151 and 152 .

Perpendicular to lines 157 and 158 , a line of symmetry 159 is arranged in the housing, which also divides the catapult and the entire housing into two equally large masses.

function

Viewed from the line of symmetry, the two masses 151 and 152 are to generate two first impulses of the same size after being ejected from the catapult holder 153 , as a result of which they move towards the housing bases 161 and 162 at the same speed (measured on the rest of the device as a reference system) and at the same time (time measured on the line of symmetry 159 ) always have the same distance from the line 159 , as is to be expressed by the distance labels a 1 to a 5 .

The mass 151 , consisting of the described parts 155 and 156, is now to be driven apart during their movement to the housing bases by means of an electromagnetic interaction and then brought together again, as is expressed by the curves 163 .

Consider the lines 157 and 158 as the x-axis and the line 159 as the y-axis and designate the intersection of these coordinates with S (where S should also be the center of gravity of the device as long as the masses 151 and 152 are still in the catapult and no electromagnetic alternating effectively carried out), it can be to the movement of the masses 151 and 152 follow ing say when the rest of the device after the ejection of the masses 151 and 152 continue (as non-accelerated reference system inertial system) is considered.

The partial masses 155 and 156 of the masses 151 and 152 move after leaving the catapult at constant speed v 1 = v 2 to the housing bases 161 and 162, respectively. The speed v 1 = v 2 of the two masses 151 and 152 is related. the axes 157 and 158 also remain constant when the partial masses 155 and 156 of the mass 151 pass through the trajectory curves 163 by means of an electromagnetic repulsion or attraction. However, mass 151 does not remain constant.

For this electromagnetic interaction, energy is required according to the formula E = mc _o ² and because of the energy-mass equivalence, the mass denoted by 151 , which is composed of parts 155 and 156 , must decrease by the amount Δ m.

The two masses 151 and 152 reach the housing bottoms 161 and 162 at the same time and at the same speed and generate two second and opposite opposing pulses, which are not of the same size, however, because according to the pulse set, the amount of movement is transferred to the device bottoms.

If the original mass 151 is denoted by m 1 and the mass 152 by m2, then taking into account the mass loss Δm - due to electromagnetic interaction - when striking the housing bases 160 and 161, the following relationship results, the common center of gravity of the masses 151 and 152 should be preserved:
(m 1 - Δm) v 1 = m 2 v 2 . In this formula: Δm = E / c _o ² = energy consumption;
m 1 = m 2 and v 1 = v 2 = velocity of the two masses 151 (m 1 ) and 152 (m 2 ), measured on axes 157 and 158 . The speed on the axis perpendicular to it (corresponds to line 159 ) can be disregarded.

However, since Δm = E / c _o ² is consumed as force field energy, when the masses m 1 -Δm and m 2 strike the housing bases 161 and 162, a resulting device pulse results from the initial center of gravity in direction A, the center of gravity of the device being briefly accelerated and migrates from S towards S '.

The mass loss Δm is thus found again in the changed movement size. From this consideration it can be seen that also inner Forces contrary to the previous doctrine change the size of the movement.

The effect just derived can be increased by a factor of 10 ⁵ and more if an appropriately suitable configuration is selected.

annotation

The accelerations and the composite speeds that occur with the mass 151 during the electromagnetic interaction are comparable to the horizontal throw, which is also under the action of a force field, but the gravity, in contrast to electromagnetic forces, not in their size and their Direction can be timed. Literature of the horizontal litter is attached. It can be seen that and with the horizontal throw they are getting bigger. In Fig. 1a there is sometimes an analogy to the litter consideration.

The speed component (see attachment) always remains constant.  

In Fig. 1b, the movement of the masses m 1 and m 2 in a closed system (housing) described in Fig. 1a is again explained in more detail, the speed components th at the distance a 3 'being shown for the partial masses 155 and 156 of the mass m 1 are that arise under the influence of the Ka tapultimpulses and the electromagnetic field.

While the mass m 2 moves in a straight line on the housing base 162 in the right-angled XY coordinate system and is therefore Vy = 0, the partial masses 155 and 156 of the mass m 1 additionally perform an electromagnetic movement during their movement to the housing base 161 , as expressed by trajectory 163 . Energy according to the formula E = mc _o ^{2 is} required.

In the right-angled XY coordinate system, the velocity components -Vx and -Vy or + Vy therefore result at a distance of a 3 ′ on the trajectory 163 for the partial masses 155 and 156 of the mass m 1 .

From the equations
x = Vx t for a uniform rectilinear movement (t = time)
+/- y = bt ² for the additional electromagnetic acceleration respectively
y = Vy t for the uniform movement y at the turning points results in the trajectory 163 . Note that the acceleration labeled b above is not constant. For a constant acceleration value b, the field strength would have to be continuously adjusted when the distance between the two partial mass electromagnets 155 and 156 changes .

It can also be seen that both masses m 1 and m 2 with respect to the X axis always have the uniform speed -Vx and Vx, respectively, which result from the catapult pulses of m 1 and m 2 , and that the mass m 1 - be depends on the energy required for the electromagnetic interaction - mass substance loses.

The device frame with the double catapult 153 therefore remains (since next m 1 = m 2 ) during the catapult pulses (first pulses) and during the movement of the masses m 1 and m 2 or m - Xm and m 2 to the housing bottoms 161 and 162 unaccelerated.

Only with the second pulse, ie when the masses m 1 - Xm and m 2 reach the housing bottoms at the same time, does the device experience an acceleration due to the resulting pulse in direction A, which results from (m 1 - Xm) v 1 = m 2 v 2 results.

If one were to design receiving devices on the bottoms 161 and 162 as catapults (similar to catapult 153 ), the remaining masses could be returned to catapult 153 and the described process started again.

With constant ejection speed from the catapults and periodically repetitive movements of the reciprocating masses, the mass m 1 would become ever smaller and the speed of the device in direction A would increase continuously (based on the initial inertial system).

Claims (2)

1. Drive device, characterized in that 2 masses are moved to the housing bases in a catapult housing, and that an electromagnetic attraction and / or repulsion takes place with a mass during the movement to the housing base. 2. Drive device according to claim 1, characterized net that several of the described masses in a housing after principle shown can be arranged.