EP2250082A2 - Thrust and carrying force generator - Google Patents

Abstract

Thrust or carrying force generates a tubular fluid jet, which is created in that a fluid after radial acceleration in a disk-shaped driven rotor mixes with another fluid in the peripherally disposed annular chamber before being deflected in a nearly axial direction.

Description

 description

Push and load force generator

Except for missiles and balloons, the main force in aircraft is usually created by the generation of lift, which is usually generated by sufficiently fast moving wings, which are called rotor blades in the helicopter. In the case of sliders, lift surfaces are also screen-labeled surfaces which, like the wings, have an aerodynamically effective profile.

Since the buoyancy surfaces always require enough strong air flow, you usually need long runways for airplanes. In helicopters, the advantageous capability of stationary floating counteracts the limitation of the airspeed, among other things caused by the flow of the retracting rotor blades.

Method and apparatus according to claim 1 allow vertical starting and landing without limiting the airspeed (such as in helicopters), the equipment required in such devices is much easier than with helicopters or VTOL devices such. B. a HARRIER of the British Royal Air Force.

Devices according to claim 1 also offer the environmental advantage that they avoid the extreme heating of the exhaust air of today's engines. Moreover, with devices according to claim 1, a simplification of the shuttle operation in space travel is possible. The drive method defined by claim 1 is also suitable for maritime purposes, since it is not limited to air as the sole working fluid. The method is described in conjunction with the list of reference numerals and the example sketches as follows:

In Fig. 1, as usual, the amounts of energy h are indicated on the entropy s with the lines of constant pressure, wherein P1 preferably corresponds to the ambient pressure, which decreases towards P3 towards P2. A fluid (eg air) passes from the ambient state 1 in the center of a nearly disc-shaped rotor similar to a radial compressor in the approximately radially extending flow channels 12 with the state 2. Due to the designed for acceleration of the fluid channel cross-sections, the fluid undergoes otherwise in the radial compressor associated with a pressure reduction such acceleration that when leaving the nozzle-like channel openings 13 at the periphery of the rotor escapes it in state 3 and upon entering a surrounding the rotor rim annular gap 18, 19 in the manner of a Saugstrahlapparates additional fluid 28.32 from the Environment sucks to assume after passing through an adjoining almost perpendicular to the rotor plane curved also annularly arranged mixing channel area 20, the state 4. The thus homogenized Mischflufd obtained when flowing through the adjoining the mixing area annular outlet passage 21, the state 5 and generates in the form of a tubular fluid jet, the desired axial thrust. An approximate value for a possible efficiency of the thrust generation provides the track ratio 6/7, a measure of the increase in entropy in the process delivers the route 8.

The following is a description of an exemplary apparatus according to claim 1, also with reference to the drawings and the list of reference numerals:

FIG. 1 shows a cycle of the method. FIG

Fig. 2 side u. Top view from the shear & Capacity producer Fig. 3 radial section CC with axis range with bearings, freewheel grinding clutch, load space for drive, control, energy supply, etc. Fig. 4 partial section AA with control blade and jockey wheel Fig. 5 section BB in the edge region of the hood and bottom Fig. 6 Channel flow and flow at Cascading Fig. 7 Ringspalte and common outlet channel opposite

Rotors Enclosed by a flat horizontal hood 9, a flat, nearly disk-shaped rotor 11 with radially arranged flow channels 12, which are designed differently from a radial compressor for accelerating into the inner openings, rotates about an axis 10 detachably fastened to the hood plane the channels entering fluid which is accelerated in the narrowing towards the edge of the rotor channels correspondingly decreasing static pressure,

The flow channels open at the outer edge of the rotor in nozzle-like openings 13th The edge of the rotor rotates in an annular gap formed from an upper concave edge 14 attached to the hood and a lower edge with a convex profile 15 held by a circular disc-like base 16 releasably secured to the axle.

Together, both edge surfaces form a downwardly open annular channel 17 which leaves above and below the rotating rotor rim an upper annular gap 18 and a lower annular gap 19 of approximately the same width, comparable to the axial section of a suction jet apparatus.

The flowing from the openings 13 of the rotor in the mixing region 20 of the annular channel 17 fluid 30 may be with the same time the fluid flowing through the annular gaps 18, 19 and leaves through the outlet 21 of the annular channel the thruster as a tubular jet whose axial thrust can be adjusted by appropriate adjustment of the annular gaps 18,19 and the rotational speed of the rotor of the respective task.

Self-rotation of the thruster control flow sheets 22 which are arranged to be movable in the outlet region of the Riπgkanals about radial, horizontal axes 23 adjustable. They also allow horizontal translational movements with the thruster.

Possibly occurring axial vibrations of the plane of the rotor 11 limit mounted on the disc-like bottom support rollers 24 which are arranged on a circle that the amplitude of possible vibrations of the rotor plane remains limited.

The disk-like bottom 16 under the rotor engages in the areas 25,26 of the flow sheets 22 in the lower edge 26 of the hood positive and non-positive, Fig. 4, 5 and thereby prevents its tilting or rotation relative to the axis 10th This ensures that arranged in the middle of the floor below the rotor in the loading area 37 drive and control devices and the energy supply unimpaired can fulfill their function.

The inflow of the fluid takes place at the top of the hood. In this case, the upper annular gap 18 is supplied by the lower annular opening 27 of the hood with the subset 28 and the lower annular gap 19 by a subset of the fluid passing through the upper inlet opening 29 of the hood after branching off the amount 30 for the rotor by the rotor hub area 31 and then flows in below the rotor, wherein this fluid portion 32 can also take over any cooling of the drive.

Reibungsmindemde thrust bearings take on the axial forces of the rotor, a lower bearing 35 and an upper bearing 36, with equal thickness washers, (each a lower 34 and two upper 33) allow adjustment of the annular gaps 18, 19.

The drive of the rotor via an electric motor with gearbox in the loading area 37 below the rotor. For the braking of the rotor, a freewheel grinding clutch 38 is provided, on which the axially guided rotor 11 is placed before the axle is connected to the hood at the upper axle end 39, so that the positive engagement of the hood 9 and disc bottom 16 in the areas 25, 26th the control leaves 22 is created by placing the hood.

LIST OF REFERENCE NUMBERS

h enthalpy of the fluid p1 ambient pressure p2, p3 pressures lower than p1 with p3 <p2 s entropy of the fluid

1 environmental condition

2 entry state in rotor

3 exit state from rotor

4 condition after mixture

5 Condition in the tube-like jet

6 jet velocity energy

7 Total process energy

8 entropy increase of the fluid

9 hood

10 supporting rotor axis

11 rotor

12 radial flow channel

13 nozzle-like opening

14 concave annular gap surface on hood / floor

15 convex annular gap surface at ground

16 disc-like rotor bottom

17 ring channel

18 upper annular gap

19 lower annular gap

20 mixing area for fluid

21 outlet area with conical side surfaces

22 flow control sheet radial, horizontal blade axis

supporting role

Floor area for positive locking

Hood area for positive engagement lower inlet opening in hood upper fluid subset upper inlet opening in hood

Fluid subset for rotor

Rotor Hub area Lower fluid subset Upper washer Lower washer Lower thrust bearing Upper Axial bearing

Loading area in the ground

Freewheel loop upper axle end upward curved channel inlet upper annular gap, concave lower annular gap, convex common outlet channel upper rotor lower rotor inner rotor outer rotor

Claims

claims

1. thrust and Tragkrafterzeuger, characterized in that in the near-natural inlet openings one of a horizontal, flat, circular, lightweight, dimensionally stable, sufficiently strong hood 9 on the upper side and a releasably connected to this hood, vertical axis 10 rotating, also flat, nearly disc-shaped, driven rotor 11 with radial, narrowing towards the outer edge of the flow channels 12 fluid flows and which is accelerated in the channels such that, after emerging from the outer rotor edge located nozzle-like channel openings 13 at the entrance to the downwardly curved annular, located between the hood and disc-shaped bottom 16 mixing channel area 20 can be mixed with additionally formed by above and below the outer rotor edge of the hood and disc-shaped bottom, adjustable annular gap 18,19 sucked fluid and when leaving the annular outlet channel 21 a The tubular jet generates an axial thrust in accordance with the course of the process according to FIG. 1 and its swirl is also made controllable by control blades 22 in the flow channel and the rotor speed.

2. thruster according to claim 1, characterized in that its principle of action according to FIG. 1 also allows a cascade-like connection of an inner and an outer, then annular thruster, wherein the tubular exit jet of the inner rotor forms the inflow of the outer rotor according to the passage of FIG 6, wherein the inlet channel openings 40 of the outer rotor are designed curved upwards in an annular manner and the two rotors 46, 47 can also rotate in opposite directions.

3. thruster according to claim 1, characterized in that a

Combination of two opposing such rotors can be made such that the flat undersides of the rotors 44, 45 facing each other and a corresponding annular gap 41 above the upper outer edge of the upper rotor 44 forms and a lower ring 42 below the lower lower edge of the lower rotor 45 forms, both of which, as indicated in Fig. 7, open into a common mixing and Ringauslaßkanal 43.