DE2442004A1 - Multi-disc gyro has main disc with bearings for planet discs - driven from stationary conical gear concentric with main shaft - Google Patents

Abstract

The gyro assembly comprises a main rotary gyro disc and a number of planetary discs rotatably carried in bearings in the main disc with their axes inclined relative to the axis of the main disc. The drive shaft of the main disc extends through a stationary conical gear wheel which meshes with conical gear wheels on the shafts of each of the planet discs. It is claimed that, for the same total weight, the total kinetic energy stored is increased. The discs may consist of plastic-impregnated man-made or glass fibre fabric laminations and the plastic may be loaded with pulverised heavy metal.

Description

Re: multi-gyro memory.

Patent description.

As known, it is assumed that you use a very quickly Gyro of conventional construction running in a vacuum or an H atmosphere. Especially for driving a vehicle, the gyro being a rechargeable energy store represents.

The present construction is characterized in that the energy-storing gyroscope does not consist of a single compact cup, but rather consists of several individual gyroscopes arranged in a certain way, the so-called.

Planets, composed.

The idea of the invention is as follows: Several gyros a, b, c, d are arranged on a main gyro A combining them so that they are with this one Form unity.

This unit represents the total top with the mass of the individual top a, b, s, d plus the wetness of main top A.

The individual gyroscopes or planets a, b, c, d are with their bevel gears Via the fixed bevel gear I with one another and with the main gyro A through their storage connected in such a way that they also transfer their rotational energy to them.

This ensures that with the same weight of the system, the multiple Energy can be stored. Namely through the rotational energy of the entire system Eß plus the individual rotational energies of the individual planetary gyroscopes a, b, ß, d where is V EA + Ea + Lb + Ec + Ed = total rotational energy of the multi-gyro system Mass m to be used for 3A = m + ma + mb + mc + md).

In order to be able to store as large an amount of energy as possible, the Speed can be very high. A simple strength problem arises here for the main gyro. (The special structure of the gyroscope body will be dealt with separately) the Assumption that the body t of the main top A can move through the planets a, b, c, d in terms of strength are inadmissibly loaded by the zontrifugal force, does not apply. As a result of the Coriolis effect, the planetary tops are kept on their orbit and can move neither remove nor become from the center (the axis of the overall gyro system) attracted to this. Have the bearings for the planetary gyro in main gyro A. so essentially only a management task or they take you from the planet outgoing rotational forces in the direction of rotation of the overall gyro.

The Coriolis force k = 2m. #. V (where # is the angular velocity of the The main gyro A is and v is the translational speed of the planets relative to the Ilauptkreisel A.) The Coriolis force k is perpendicular to the vectors # and v By dividing the total mass of the gyro into individual gyroscopic ones Parts that move in the precession plane of the overall system are achieved that the motif of the gyro system is used multiple times.

Namely through the rotational energy of the overall system and additionally through the sum of the rotational energies of the individual planetary gyroscopes.

Structure of the gyroscope body.

In order to be able to store as much energy as possible in the gyroscope, is a speed that goes up to the strength limit of the material used is necessary. This requires a special material as well as a special construction in the construction the top body.

The starting point is the principle of Snerrholz, i.e. gluing of diagonally offset fibers.

In the present case, it is synthetic fiber or. Glass fiber fabric whose strength is close to that of the best steel.

These tissues are placed against each other diagonally with a suitable plastic connected to a compact cup. (1 sheet 2) Between the individual days of the In order to achieve the necessary weight, tissue becomes a metal powder - especially lead -evenly, but decreasing in quantity from the center, distributed. (2 sheets 2). This ensures that the strength of the circular body remains the same the weight towards the periphery to the strength ratios: adjusted accordingly will can and that the gyro body remains elastic but still of high strength.

Claims (1)

Claims. 1.) On the use of several gyroscopes, which are described in the Way are connected. These gyroscopes form the overall gyro system with their individual masses. This consists of the main top and the individual circles, the so-called planets. These Planets rotate in the main gyro plane around the main axis and are via bevel gears with each other non-positively connected via the fixed Kegelsad I, whereby they give their rotational energy to the main gyro A via their storage. This makes it possible, with the same weight of a gyro, that kinetic energy of the total mass by dividing it into several by one common axis of rotating individual gyroscopes, which are frictionally engaged in the type described are interconnected to increase. The special structure of the gyroscope bodies. The top body consists of individual, highly tear-resistant layers stacked on top of each other Synthetic fiber or glass fiber fabrics which by means of a suitable plastic adhesive be combined under pressure into a compact hat. The essentials However, it consists in that the said plastic adhesive to achieve the necessary gyroscopic mass is made into a paste with a heavy metal powder such as lead. By changing the concentration in the composition plastic - The weight and strength of lead can be adjusted according to the position in the gyroscope body will. Another possibility is, instead of the metal powder, a thin one is used perforated metal foil placed between the individual fabric layers and through the adhesive bonded to the fabric layers. The above layers of tissue are each offset diagonally from one another.