DE19908225A1 - Gravity engine for rotary drive combines Coriolis force, mass inertia, and centrifugal force to act in addition to flow energy - Google Patents

Abstract

The engine has a rotor (21) with impeller (5), pref. vane cell turbine, and a transmission (6,8). A fluid flows from the center of the engine to the impeller, which rotates about that center. The impeller drives the rotor via the transmission against the fluid flow. Due to this, and in addition to the flow energy, the resultant of the gravity forces of Coriolis force, mass inertia, and centrifugal force act in movement direction of the rotor. The transmission consists pref. of toothed gear (8) and rim (9), chain wheel and chain, or elastomer rollers.

Description

technical description

The gravitational motor for use as a rotary drive consists of an impeller ( 5 ) located on a rotor ( 21 ), a flow channel ( 1 ) and a gear ( 8 ) which is toothed with a ring gear ( 6 ). In addition to the flow force, the gravitational motor is driven by the Coriolis force ( 11 ), inertia and the centrifugal force ( 12 ). A fluid flows from the center of the gravitational motor ( 3 ) via the flow channel ( 1 ) to the impeller ( 5 ). The Coriolis force ( 11 ) acts against the direction of rotation ( 15 ) and presses on the vanes ( 16 ) of the impeller ( 5 ). The impeller ( 5 ) is thus accelerated and drives the rotor of the gravitational motor ( 21 ) via the gear ( 8 ) and the ring gear ( 6 ). With the fluid flowing through the rotor ( 21 ), the gravitational motor can deliver mechanical energy to the pulley ( 19 ). In the starting phase, the flowing fluid ( 2 ) first drives the rotor ( 21 ) to speed, the drive energy being increased continuously with the speed increase due to the Coriolis force ( 11 ) and the centrifugal force ( 12 ).

State of the art

Existing water turbines use almost only the flow force or that Weight of the fluid. In contrast, the gravitational motor uses next to the Flow force and weight also the gravitational forces.

Achieved advantages

If you move z. B. on a rotating disc ( 10 ) a mass ( 13 ) in a groove ( 14 ) from the center to the edge of the disc, the Coriolis force ( 11 ) counteracts the rotational movement ( 15 ) during the movement of the mass ( 13 ).
Coriolis force = 2 muω
m = mass
u = flow velocity.

If the mass ( 13 ) does not move during the rotational movement in the groove ( 14 ), the mass ( 13 ) generates a centrifugal force ( 12 )
Centrifugal force = m.ω ² .r
m = mass
r = radius.

If the mass ( 13 ) on the accelerated disc ( 10 ) is guided into the groove ( 14 ), an moment of inertia arises that counteracts the rotational movement ( 15 ).
Moment of inertia = mb = m.ω.r
m = mass
b = acceleration
r = radius.

If the mass ( 13 ) in the groove ( 14 ) moves continuously in the form of a fluid on an accelerated disc ( 10 ), then in an accelerated reference system, several forces act as a braking effect. An advantage achieved by this invention is the reversal of the resulting gravitational forces with mechanical help from the braking action to the driving action. By using the resulting gravitational forces, new ways of generating drive energy have become possible.

Embodiment

The embodiment of the invention will be described with reference to FIG. 2, Fig. 3 and Fig. 4.

Fig. 2 shows the section of the impeller as a vane cell turbine.

Fig. 3 shows a vertical section through the center of the gravitational motor.

Fig. 4 shows a horizontal section through the center of the gravitational motor at the level of the flow chamber ( 1 ) with ring gear ( 6 ) and flow direction ( 2 ) of the fluid.

The components of Fig. 2, Fig. 3 and Fig. 4 have the following meanings.

1 flow chamber
2 fluid flow
3 Fluid supply to the gravitational motor
4 turbine housings
5 vane cell turbine as vane
6 ring gear
7 bearings of the gravitational motor
8 gear
9 turbine bearings
16 vanes of the vane cell turbine
17 Fluid output of the vane cell turbine
18 shaft of the vane cell turbine
19 pulley
20 rotor of the vane cell turbine
21 rotor of the gravitational motor

The fluid flows (2) (1) a Coriolis force (11) acting against the rotational movement of the gravitational motor from the fluid supply (3) through the flow chamber (1) to the vane turbine (5) is produced by the rotation of the gravitational motor in the flow channel. The Coriolis force ( 11 ) presses on the slide ( 16 ) of the vane cell turbine ( 5 ). The vane cell turbine ( 5 ) is accelerated further and drives the gearwheel ( 8 ) via the shaft ( 18 ) of the vane cell turbine ( 5 ). The gear wheel ( 8 ) interlocked with the ring gear ( 6 ) accelerates the rotor ( 21 ). The acceleration of the rotor ( 21 ) by the vane cell turbine ( 5 ) also increases the centrifugal force ( 12 ) of the fluid. The fluid ( 2 ) accelerated by the centrifugal force ( 12 ) compresses in the flow chamber ( 1 ) and also presses on the vane cell turbine ( 5 ). The resultants of the inertia, the Coriolis force ( 11 ) and the centrifugal force ( 12 ) together accelerate the vane cell turbine ( 5 ) and thus the rotor ( 21 ). This is only possible if the gravitational motor with a starting aid z. B. is brought up to speed by a fluid flow ( 2 ).

The vane cell turbine ( 5 ) consists of a housing ( 4 ) with a truncated cone bore in which the rotor ( 20 ) is mounted eccentrically. In its radial or tangential longitudinal slots slide ( 16 ) slide, which are pressed by the centrifugal force or cams on the inner housing wall and thereby their volume changes during a rotor rotation between minimum and maximum. The vane cell turbine ( 5 ) is arranged so that the gyroscopic effect does not hinder the acceleration of the gravitational motor.

Claims (10)

1. Gravitational motor for use as a rotary drive, consisting of at least one rotor ( 21 ) arranged impeller ( 5 ) and a gear ( 6 , 8 ), characterized in that from the center of the gravitational motor a fluid ( 2 ) to around the center of the Gravitational motor rotating impeller ( 5 ) flows, the impeller via gear ( 6 , 8 ) drives the rotor of the gravitational motor ( 21 ) against the fluid flow ( 2 ), so that in addition to the flow force, the resultant of the gravitational forces, the Coriolis force ( 11 ), the inertia and the centrifugal force ( 12 ) acts in the direction of movement of the rotor ( 21 ). 2. Gravitational motor according to claim 1, characterized in that a plurality of impellers ( 5 ) can be arranged on a rotor ( 21 ). 3. Gravitational motor according to at least one of the preceding claims, characterized in that the impeller ( 5 ) consists excellently of a vane cell turbine. 4. Gravitational motor according to at least one of the preceding claims, characterized in that the gear consists primarily of gear ( 8 ) and ring gear ( 9 ), sprocket and chain or elastomeric rollers. 5. Gravitational motor according to at least one of the preceding claims, characterized in that the fluid ( 17 ) emerging from the impeller ( 5 ) flows onto standing blades and is used as a recoil force. 6. gravitational motor according to at least one of the preceding claims, characterized in that the gravitational motor is also used as a water turbine can be used. 7. Gravitational motor according to at least one of the preceding claims, characterized in that the Coriolis force ( 11 ) generated by the fluid moving on the rotor ( 21 ) acts on the impeller ( 5 ). 8. Gravitational motor according to at least one of the preceding claims, characterized in that the centrifugal force ( 12 ) resulting from the rotation acts on the impeller ( 5 ). 9. Gravitational motor according to at least one of the preceding claims, characterized in that the fluid flowing in through the center ( 3 ) of the gravitational motor acts on the impeller ( 5 ). 10. Gravitational motor according to at least one of the preceding claims, characterized in that the gyroscopic action of the impeller ( 5 ) does not hinder the rotational movement of the gravitational motor.