NL1040809B1 - Method to extract electrical energy from the environment. - Google Patents

Abstract

In a vacuum tube, electrons can be accelerated in such a way that, due to inertia or transition into electromagnetic radiation, they shoot past the electrode with which they are attracted, and then become available on another electrode. In this way, the attracting load remains intact, and therefore continues to attract new load. With the help of such a tube and high-frequency high voltage, electricity can be extracted from the atmosphere.

Description

Method for extracting electrical energy from the environment Introduction

Our atmosphere, or the ether as you wish, is bursting with electrical energy. This is mainly from the sun and expresses itself, among other things, in a thunderstorm. Giving us access to this electricity opens up a new source of renewable energy.

The operating principles that make this possible are all well-known and proven techniques.

Electric aeleidina of the air

Under normal circumstances, the air is an insulator. This fact limits the amount of energy that we can extract to a small volume. If we could make the air conductive, we suddenly have all the electrical energy in the entire atmosphere. To gain access to industrial quantities, we must therefore use techniques that make the air electrically conductive. Three methods are known for this: 1 - Air pressure reduction. By going to a great height, the air pressure decreases and thus the electrical conductivity increases. 2 - Application of high-frequency alternating current. The higher the alternating current frequency, the better it is passed through the air. 3 - Application of high voltage. As the electrical voltage becomes higher, the conductivity through the air increases.

Finally, there is a fourth, less known method; namely, around a high-frequency Tesla coil, the conductivity of the air, as long as it is on, increases measurably.

By applying one or more of these techniques or methods, the area from which we can draw is enlarged.

Attracting electricity from the air

It can be generally assumed that positive charge attracts negative charge, and vice versa.

With the help of a large positive charge, we can attract negative charge. As soon as this charge is attracted, however, it neutralizes the positive charge and with that we lose energy. We must therefore ensure that the attracted load remains separate from the load with which we attract it. This can easily be achieved in a slightly modified Crookes tube.

Namely, in such a tube electrons are emitted from the cathode which due to their momentum shoot past the anode. By capturing this through a third electrode, we can have the attracted charge without neutralizing the attracting charge.

Save the attracted load

By connecting this third electrode to a capacitor whose other side is connected to earth, we can store the attracted charge. This charge can then be made available from this capacitor.

In addition, a provision can be made to use the charge that has been taken out of the earth with this, ie the other side of the capacitor, to pull new charge out of the air.

Use of alternating voltage

If alternating voltage is used, we must apply a (permanent) magnetic field over the Crooks tube with which we separate the positive and negative charges, so that the third electrode only receives the desired negative charge. Of course, a fourth electrode can then be applied to collect the positive charge.

An alternative is to make the alternating voltage asymmetrical, so that it is mainly positive or, on the contrary, mainly negative.

Description on the basis of the image

Referring to Figure 1; A is the anode on which a high positive voltage is applied, K is the cathode to which an antenna with a large surface area is connected, O is the third electrode which forms the output for the collected electricity.

The anode attracts charge via the cathode from the atmosphere. To prevent a charge being also attracted from the output (O), a diode can be included in that circuit. The attracted charge is transferred as a cathode beam to the output electrode (O), and stored there from within a capacitor.

Alternatively, the third electrode can also be placed outside the tube, as in Figure 2. With a sufficiently high voltage, charge is then also transferred to this electrode by means of radiation.

Not in these images:

Electrostatic shielding is used to protect the vulnerable parts of the pipe.

If alternating voltage is used (at A, the anode), the electron beam must be directed to the third electrode (O) by means of a magnetic field. In this way it is prevented that also positive ions end up on that electrode.

The output electrode (O) is connected to earth via a capacitor.

Claims (6)

A method of extracting electrical energy from the environment characterized by separating the attracted charge from the attracting charge and making it available. Method as claimed in claim 1, characterized by attracting it and accelerating it in a vacuum tube in such a way that it overrides the electrode with which the charge is attracted, and becomes available on another electrode. A method according to claim 1 characterized by attracting it and accelerating it in a vacuum tube so that, in the form of radiation, the electrode with which this charge is attracted falls past, and becomes available on another electrode. Method according to claim 2 or 3 characterized by using alternating voltage to attract the charge and then splitting the attracted charge into a positive and negative beam through a magnetic field of which only the desired charge, positive or negative, on the decrease electrodes. Method as claimed in claim 2 or 3, characterized by using alternating voltage to attract the charge and subsequently splitting the attracted charge by means of a magnetic field into a positive and negative beam directed at different electrodes. Method according to claims 1, 2, 3, 4 and / or 5 characterized by increasing the conduction of the air by using a low air pressure and / or a high electrical voltage (more than 100 KV) and / or a high frequency alternating voltage (more than 100 KHz).