DE102004024142A1 - Gravitational force propeller for power generation, has rotary symmetric double lever with same-length lever arms whose ends are blocked, where moveable load is applied on each arm - Google Patents

Abstract

The propeller has a rotary symmetric double lever with same-length lever arms whose ends are blocked. A moveable load is applied on each arm. The loads are guided by a stationary and variable guidance system during the rotation of the double lever, in a previously described orbit, through a stationary and variable control system. The propeller is made of blocks that are assembled from base units which are displaced at specific value.

Description

Today's power plants use mostly fossil, nuclear or renewable energy,
characterized,
that the resulting high emission levels must be throttled or the spent core rods must be disposed of by very expensive safety precautions.

Schematic representation of the basic element (Figure page 3)

If one looks at the basic element in the unit circle and sets the mass used to 1.000, the following relationship arises: The system is divided into four sectors. The starting point is the point "0", which has the position 0 ° or 360 ° and is located on the horizontal left by the center of the axis with the maximum distance from the center of the axis top left sector 4. At each transition point there is a center of gravity: A ₁ = 0 °, A ₂ = 90 °, A ₃ = 180 °, A ₄ = 270 ° The center of mass A ₁ moves in the sparkling wine 1 on a quarter circle arc r = maximum distance, in champagne 2 it is brought by a control system to the minimum distance to the center axis, continued in champagne 3 by another control system to return in champagne 4 via a control system in the quarter circle arc with r = maximum distance to the starting point The other three centers of gravity inevitably also make one circulation only from other starting positions, with one complete revolution of one center of mass constantly changing the effective lever arm length (horizon taler distance of the center of mass to the vertical through the center of the axle). At a 90 ° turn you get different force and Lastarmlängen. The fixed levers are always working together. There are always power arms in Sector 1 and 4 and always Load arms in Sector 2 and 3. The distance between the two levers must be greater than the thickness of the weights. The ratio of maximum to minimum distance can be chosen freely. In the schematic diagrams, 5: 1 has been used.

There the common center of gravity of the four individual centers of mass at a 90 ° turn does not assume a stable position in sector 1, but shuttles back and forth, For its stabilization n basic elements - offset by 90 ° / n - become one Block composed. m of such blocks - each offset by 90 ° / (n × m) - result assembled an aggregate with stable common center of mass and constant torque. In the schematic representation is n = 8 used.

Control Systems:

The Control systems in Sectors 3 and 4 are stationary and Sector 2 variably mounted. This gives you the opportunity when retracting the control system to throttle the rotation and the To increase the torque continuously up to the maximum.

weights:

When Weight can be e.g. a flat cylindrical disc, in the middle parallel to the diameter of a rectangular opening for recording the lever arm is attached, use; every other form is possible. At the ends of the opening is ever a flattening for recording and Fixing the guide frame - equipped with 2 horizontal and vertical roller bearings each - provided. In the district center On both sides are each an impeller attached, with which the weight in Sector 2, 3 and 4 rolls on the control systems and the weight in the given position.

reached advantages

Since the unit operates emission-free, the environment is not polluted. In 2002, total electricity generation in Germany was 504 billion kWh, of which 60% was generated by fossil fuels, 31% by nuclear energy and 9% by renewable energy.) When using the unit omitted the storage of the fuel, the disposal of the combustion residues / -Elements, the Entgasungsanla conditions, etc.

Calculation possibility of the torque at the basic element: Power arm · Force = load arm · Force + torque Force (power arms - load arms) = torque 1 · (power arms - load arms) = torque Effective torque of the unit (ratio X: 1) Torque = n · m · 1 Weight · Radius) 2 ·Factor

Horizontal distance of the center of mass from the vertical through the center of the axis in the unit circle of the schematic representation divided into maximum: minimum ratio

Horizontal distance of the Center of gravity from the vertical through the center of the axis in the Unit circle result = effective torque in the unit circle Snapshot at the block or 90 ° turn of the primitive

Ratio 5: 1

• Sum / Block = 7.484, average per primitive = 0.936 Units = factor

Ratio 10: 1.5

• Sum / Block = 8,164, average per primitive = 1,021 Units = factor

Ratio 10: 1

• Sum / Block = 8.726, average per primitive = 1.091 Units = factor

Claims (1)

To drive generators to use an aggregate, which is driven by gravity and consists of the following basic element, characterized in that 1) a rotatable symmetrical double lever with equal length lever arms whose end are blocked. 2) There is one movable weight on each lever arm, all four are identical. 3) By means of targeted guidance systems, the individual weights are positioned in such a way that a torque is generated by the constant and permanent presence of gravity.