DE228654C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

- M 228654 - ■ CLASS 77 h. GROUP

Patented in the German Empire on February 21, 1909.

According to the present invention should be directly below (or behind) a suitably trained rigid wing due to rapidly following inflammation of an emerging through fine channels An explosive mixture, a pulsating pressure acting on this surface is generated, which is suitable to keep the balance of the force of gravity or resistance or overcoming it, and so climbing up and moving the apparatus bring about in the air.

It should not be the reaction force of a nozzle device in the direction of movement in the opposite direction escaping into the atmosphere at great speed Compressed gas can be used as a propulsive force, but rather in the implementation of the new principle, no compressed gas is generated in a closed space at all. That The explosion mixture only receives so much overpressure that it passes through fine channels under the The wing emerges, and is detonated there in such a way that it that not a constant, but an intermittent combustion process is entertained. The apparatus thus receives rapidly successive shocks or movement impulses, which in their entirety are a the force of gravity counteracting and possibly overcoming the same tension or compressed air produce.

The more often these impulses occur per unit of time, the smaller the size fluctuations this uplift or propulsion force fail. With an infinitely high frequency of Momentum, this force would be constant. The wing is unchangeable with the flying machine, or else yieldingly connected in such a way that only a rectilinear mutual Shift can take place within certain limits.

To explain the essence of the invention, an apparatus for climbing is on the drawing Illustrated schematically in the air in an exemplary embodiment, namely in Fig. ι the overall arrangement of the "page seen and in Fig. 2 a part of the wing in section on a larger scale.

A second rigid surface 5 is attached to the rigid support surface T by means of preferably tubular rods P , on which the necessary apparatus are set up. These consist mainly of a device for producing the explosive mixture and a current interruption device which causes the explosive mixture to ignite directly below the wing T. The first-mentioned device consists in the present case of the container A for a suitable fuel, for. B. gasoline, and the carburetor C, through which air is driven through by means of the fan D with electrical

drive motor E, which is fed by the power source F. The gasoline does not enter the carburetor C directly from the container A, but through an intermediate container B, in which the fuel level is kept constant by means of a float device. The fuel is introduced into the carburetor C and brought into close contact with the air passing through it. The here

ίο forming explosive mixture passes through one or more tubes P and Q into the cavity O of the wing and flows out of this through many tubes R distributed over this area and open at the bottom (Fig. 2) in uninterrupted fine jets into the atmosphere, in order to escape to be burned by explosions in rapid succession. To bring about the explosions, a power source G is used in the embodiment shown, in whose circuit there is an interrupter H , one line being connected to the wing T and the other to a plate M (Fig. 2) which is isolated from it and located on its lower side is. L and N are isolation plates. In the event of a current connection, sparks will form between M and the tube R and ignite the explosive mixture that has escaped.

Through a valve on the fuel supply line and through an air valve on the carburetor, which is used for Intake of atmospheric air is used, the mixing ratio of fuel and Air in the explosion mixture or its explosive force are changed in such a way that at Constantly remaining frequency of the explosions a buoyancy, a suspension or a Relegation takes place. The same result can also be achieved by changing the frequency of the Explosions can be achieved.

The horizontal movement in the air can be brought about by a similarly designed vertical propulsion surface or by the known screw propellers. If the surface T is set at an incline, lift and propulsion are achieved at the same time. The apparatus can also be controlled by explosions under inclined and possibly changeable surfaces, and this control method can optionally be used in addition to the known control devices.

In order to take account of the blowing off of the explosive mixture through the air when the apparatus is advanced quickly, the wing T can be extended in the rearward direction (generally in the direction in which the explosive mixture is blown off), which instead of the gas outlet tube R full Has pins for spark formation, so that the explosive mixture caught there is still caused to ignite.

The blowing off of the explosive mixture emerging in fine jets can also be suitable adjustable protective surfaces on the leading edge of the wing eliminated or weakened will. . .

The explosions, which follow one another as quickly as possible, must reach their conclusion as quickly as possible, so that a steady combustion process does not develop and explosion from explosion always remains as sharply separated as possible in time. This is a basic requirement for the practical feasibility of the apparatus. In the case of a liquid fuel (e.g. gasoline), this mixture must be a vapor gas mixture, since even the finest droplets (mist) would slow down the explosion and consequently weaken the impulses to be communicated to the wing. In order to achieve this, a carburetor with preheating of the gasoline or the like is expediently used, or the finished mixture is heated before it escapes into the atmosphere. A suitable temperature can be maintained in the chamber O for this purpose.

Since the tubes R with the fine channels only prevent the explosion from spreading into the chamber O if their temperature is below a certain limit, and since an uninterrupted combustion process would occur if the outlet ends of these tubes were overheated, they must be cooled and possibly also for the cooling of the plate M taken care of. This can be achieved through air or water circulation. In order to make the large cavity O filled with the explosive mixture unnecessary, which could be dangerous under certain circumstances, each tube R can be connected directly to the feed pipe P or several such appropriately grouped tubes. In this case, the supporting surface is formed by the insulation plate L and the lower metal plate M. In this case, ie if there is no large collecting space O , the explosion mixture can also be blown jerkily through the tube R into the atmosphere, in which case the frequency of the gas surges and the spark formation must of course be precisely timed, which is achieved by various known means can be.

Claims (2)

Patent Claims: i. Device for ascending and moving in the air by recoil exploding Gas mixtures, characterized in that the finished mixture by fine pores of a rigid wing occurs and is caused to explode in front of it. 2. Embodiment of the apparatus according to claim i, characterized in that the rigid support surface (T) has an insulated metal plate (M) through which the annular projections of the insulation plate (L) penetrated by the fine gas outlet tubes (R ) emerge, the explosions of the gas mixture can be brought about by electrical sparks generated between R and M. For this purpose ι sheet of drawings. Berlin, printed in the Reichsdruckerei.