DE10354019A1 - Apparatus to receive/transmit/store waves affecting gravity, for precision weighing, has a structure of electrically conductive and non-conductive plate layers in a packet - Google Patents

Abstract

The apparatus (10) to receive, transmit and/or store at least part of the energy from waves, which affect gravity, has two bodies of a material which is non-conductive for an electrical current. A layer of electrically conductive material is between the two bodies. The opposite sides of the non-conductive bodies and the intermediate conductive layer have the same surface contours. The apparatus (10) to receive, transmit and/or store at least part of the energy from waves, which affect gravity, has two bodies of a material which is non-conductive for an electrical current. A layer of electrically conductive material is between the two bodies. The opposite sides of the non-conductive bodies and the intermediate conductive layer have the same surface contours. The assembly is a rotor with a diameter of 300 mm, within a vacuum vessel which can be filled with a non-flammable gas, as a packet of overlaid plates. From top to bottom there is a 6 mm thick plate of red hard PVC (11) with a polyimide film (11A) adhering to its under side, a woven ring (12) of copper wire with a diameter of 0.5 mm and a mesh width of 1 mm, a 100 mm thick plate (13) of polished Indian red granite, a further and similar woven copper wire ring (14), a 20 mm thick plate (15) of pure white marble with a 0.025 mm thick polyimide film (15a) adhesive bonded to the under side, a further similar woven copper wire ring (16) and a 6 mm thick red PVC plate (17). The assembly is energized by electrodes at a gap from the first body, using a high direct voltage of 5-20 kV.

Description

The present invention relates to Device for receiving, sending and / or storing at least one Share of the energy of waves.

The invention is based on the object to specify such devices using the energy of waves, which has an impact on have the heaviness.

The object of the invention is achieved with a device according to claim 1 solved. Advantageous embodiments of the invention are specified in the dependent claims.

In experiments the inventor has surprisingly found it turned out that in the devices according to the invention a change the heavy one observes, if the device according to the invention excited with a high DC voltage or by approaching an already excited device has been excited. The inventors are believes that these surprising but explain reproducible test results. that the Devices according to the invention receive, send and / or receive at least part of the energy from waves can save which has an impact on the weight of bodies to have.

The invention is based on the in the embodiments shown in the figures described in more detail.

1 shows a schematic representation of arrangement for exciting a device according to the invention.

2 shows an exploded view from the side of a first embodiment of the invention.

3 shows the curve of the time course of the change in the severity of the device according to 2 after excitation in an order according to 1 ,

4 shows an exploded view from the side of a second embodiment of the invention.

5 shows the time course of the change in the severity of the device according to 4 after excitation by a device according to 2 ,

6 shows an exploded side view of a third embodiment according to the invention.

1 shows an arrangement for exciting a device according to the invention. The device according to the invention is with the reference numerals 10 referred to and is related to 2 described in more detail. The arrangement has a base plate 1 and a metal frame 2 on. On the metal frame 2 is a hanging camp 4 attached to which the device 10 is freely rotatably attached. Furthermore, is on the metal frame 2 an insulating bracket 3 attached. In the insulating holder 3 are two electrodes or conductors 5 and 6 attached. The conductors 5 and 6 are connected to a high-voltage device, which is constructed in a manner known to those skilled in the art. The high-voltage device provides a DC voltage of 5 to 20 kV at a current of 0.1 to 10 μA. The distance between the conductors 5 and 6 and the device 10 is about 0.1 to 5 mm.

The conductors 5 and 6 have an electrically conductive or semiconductive material, which can also be applied in the form of a thin layer on a non-conductive carrier.

The whole arrangement according to 1 is placed in a vacuum container which has been evacuated to a pressure of approximately 1 to 10 mbar with a rotary lobe pump and into which air which has been dried through a bed of silica gel is introduced. When the arrangement is operating, there is a humidity of 25 to 45% in the vacuum container. In theory, even lower air humidity values are preferable. However, it takes more effort to achieve values lower than 25%. The internal pressure corresponds to the external pressure, so that no further air exchange takes place.

Instead of air, you can also after the evacuation other gases in the vacuum container be introduced, for example nitrogen, helium, argon, xenon, pure hydrogen, carbon dioxide and / or another non-flammable Gas or mixtures of the gases mentioned.

The conductors 5 and 6 can be formed, for example, from the following materials: approximately 0.1 to 3 mm thick metal plates or sheets made of aluminum, titanium, silver, gold, nickel, iron, both soft and steel, V2A, graphite, copper sheet covered with indium, and fabric made of copper and nickel or steel coated with diamond (diamond drill) etc.

2 shows an exploded view from the side of an inventive device for receiving and storing at least a portion of the energy of waves. For the sake of clarity, the side view shows the distances between the individual components. In the assembled state, the individual parts lie directly on top of one another and are pressed onto one another by brass screws or connecting elements, not shown. Other fasteners or techniques can also be used, such as plastic parts or potting the body and layers.

• – eine 6 mm starke Platte, 11 aus rot eingefärbtem harten PVC,
• – eine auf der Unterseite aufgeklebte Polyimidfolie 11A mit 0,025 mm Dicke,
• – einen Kupfergewebering 12 aus Kupferdraht mit 0,5 mm Durchmesser und einer Maschenweite von 1 mm,
• – eine 10 mm dicke Platte 13 aus geschliffenen indischem roten Granit,
• – ein Kupfergewebering 14, der im wesentlichen den Kupfergewebering 12 entspricht,
• – eine 20 mm dicke Platte 15 aus rein weißem Marmor,
• – eine auf die Unterseite der Platte 15 geklebte Polyimidfolie 15a mit 0,025 mm Dicke,
• – einen Kupfergewebering 16, der im wesentlichen den Kupfergewebering 12 entspricht und
• – eine 6 mm dicke rote PVC-Platte 17.

The device 10 is designed as a round rotor with a diameter of 300 mm and has the following parts from top to bottom:

• - a 6 mm thick plate, 11 made of red colored hard PVC,
• - a polyimide film glued on the underside 11A with 0.025 mm thickness,
• - a copper mesh ring 12 made of copper wire with a diameter of 0.5 mm and a mesh size of 1 mm,
• - a 10 mm thick plate 13 made of polished Indian red granite,
• - a copper mesh ring 14 which is essentially the copper mesh ring 12 corresponds,
• - a 20 mm thick plate 15 made of pure white marble,
• - one on the bottom of the plate 15 glued polyimide film 15a with 0.025 mm thickness,
• - a copper mesh ring 16 which is essentially the copper mesh ring 12 corresponds to and
• - a 6 mm thick red PVC plate 17 ,

The entire stack of plates is through three long brass screws that are symmetrical to the center, compressed, without touching the metallic conductors inside. The screws hold at the same time the bearing shell and its opposite side, which is in the center of a bracket rests. The total weight of the plate stack is approximately 10,000 g.

The device according to 2 was in accordance with the arrangement 1 used. The vacuum container including the assembly was evacuated with a rotary lobe pump and air dried over a bed of silica gel was introduced into the vacuum container. A DC voltage of 20 kV was applied to the conductors. A current of 0.1 to 10 mA was measured. The device 10 began to spin on its own and reached a speed of approximately 200 rpm after 30 minutes.

The whole arrangement including the vacuum vessel was placed on a precision balance before the start of the experiment at weights of approximately 10,000 g a measuring and has a display accuracy of 0.1 g.

Surprisingly, it was found that the precision balance indicated a change in the measured value of up to 20 g when the maximum speed of 200 rpm was reached after 30 minutes. After switching off the DC voltage, the speed of the device increased 10 gradually decrease. The change in the display was retained even after the device stopped.

So it turned out that in indeed a change the severity of the device could be observed. After done The device was broken down into excitement and the excitement Individual parts were weighed separately. Corresponded the sum of the measured values exactly the weight of the device before excitement. If you excited the parts of the according to the procedure described above Reassembling the device, the same change is again made the heaviness firmly.

The severity of the device was observed on a precision balance for six days under the same external conditions. 3 shows the change in device severity over time.

In 3 the difference in severity in grams against time is recorded over a period of six days. There is an increase in weight of approximately 12 g over the course of the six days. You can also see six distinct minima. After an increase in gravity by approximately 4 g, a decrease by approximately 2 g was observed. This course of the curve was repeated daily. Obviously, the curve correlates with the rotation of the earth.

In 4 Another embodiment of a device according to the invention is shown. The representation corresponds to that of 2 , The device 20 for receiving and storing part of the energy of waves has two marble slabs ground on both sides 21 and 23 made of white highly crystalline material. The marble slabs 21 . 23 each have the dimensions 70 mm by 25 mm by 11 mm. The two marble slabs are on the top and bottom 21 and 23 each with a polyimide film 21a . 21b . 23a and 23b with a thickness of 0.025 mm. Between the two marble slabs 21 and 23 is a pure copper mesh made of copper wire with a thickness of 0.5 mm and a mesh spacing of 1 mm. The marble slabs are pressed tightly together using clamping screws at the ends.

To manufacture the device according to 4 the two marble slabs 21 and 23 first annealed at 150 ° C for two hours, slowly cooled and then covered with a polyimide film on the top. Then the intermediate layer made of pure copper fabric is placed between the two marble slabs and the entire device is pressed together with clamping screws.

It has surprisingly been found that the device according to 4 can be excited by placing them on an excited device 2 sets. In the test carried out, the device was designed according to 4 for 30 min according to the excited device 2 placed.

5 shows the time course of the change in the severity of the device according to 4 that was excited as described above. The acceptance of the display of a precision measuring scale in grams is plotted over the course of four days.

From the curve of 5 one recognizes a time course of the decrease in gravity, which corresponds to the time course of the increase in gravity from 3 very similar. A decrease in weight of approximately 50 mg per day can be seen, with a decrease in weight of approximately 100 mg initially being observed, which decreased by about half over the course of the day when the minimum was reached. The measurement and display accuracy of the precision balance was approximately 232 g with a total weight of the device 1 mg.

From the comparison between the curve shape according to 5 and the course of the curve 3 it can be seen that the minima according to the decrease in gravity in the device 3 according to the minima of the weight increase of the device 2 corresponds and vice versa. The steep drop at the end of the curve of 5 is due to the end of the experiment.

• – eine 5 mm starke Acrylglasplatte 31, auf deren Unterseite eine Polyimidfolie 31a mit 0,025 mm Dicke geklebt ist;
• – ein Ring 32 aus feinstem V4A-Gewebe mit 0,1 mm Drahtstärke,
• – eine 10 mm starke Oxydkeramikplatte 33 (reines Aluminiumoxyd);
• – eine 6 mm starke PVC-Platte 34;
• – ein Kupfergewebering 35 mit 0,5 mm starken Kupferdrähten und einem Maschenabstand von 1 mm und
• – eine 5 mm starke Acrylglasplatte 36.

6 shows a third embodiment of an inventive device for receiving and storing part of the energy of waves in a side view. The device 30 is a circular rotor with a diameter of 300 mm. It is composed of the following parts of the same diameter:

• - a 5 mm thick acrylic sheet 31 with a polyimide film on the underside 31a is glued with 0.025 mm thickness;
• - a ring 32 made from the finest V4A fabric with 0.1 mm wire,
• - a 10 mm thick oxide ceramic plate 33 (pure aluminum oxide);
• - a 6 mm thick PVC sheet 34 ;
• - a copper mesh ring 35 with 0.5 mm thick copper wires and a mesh spacing of 1 mm and
• - a 5 mm thick acrylic sheet 36 ,

As with the device according to 2 all layers are connected with continuous brass screws.

The following test was carried out with the device: the device is in the arrangement according to 1 mounted, which in turn is arranged in a vacuum container. The entire arrangement, including the vacuum container, stands on a sensitive precision balance, which makes it possible to continuously record the change in weight. The overall device weighs approximately 4800 g. The precision balance has a measurement and display accuracy in this range of 100 mg. As described above, the air in the vacuum container was first exchanged for dried air. Then a direct voltage was applied to the conductors 5 and 6 in the amount of 20 kgV. The device started rotating rapidly and currents in the range of 0.1 to 11 µA were measured.

The following table shows the observed values, after what time, at which speeds, which changes in weight were determined:

The rotor is allowed to run out and over The change in weight is observed for a further two hours. At the end which is two hours the change in weight - 11.2 g.

It is also conceivable the present one Invention as a large-scale Training device. The devices according to the invention can, for example also weigh a few hundred kilograms up to several tons. The Thickness of each sheet could be for example, be a few meters. Likewise, the The diameter is appropriately large become. For example, the values given in the experiments above also some orders of magnitude to be taller.

The foregoing description of the "excitation" of the devices corresponds essentially to the excitation of the magnetization of the magnetic materials with the only difference that instead of the magnetism introduced into spinel lattice, gravity is "pulsed" according to the present inventors. While high currents at low voltages are used in the introduction of magnetism, high voltages at low currents are used here. Just as the magnetization in the magnetized bodies is preserved, according to the inventors' idea, the gravity is preserved as a kind of dynamic vibration. Just as the magnetization can be passed on to a suitable body by an already magnetized body, the experiments suggest that this can also be done with gravity. The The inventors believe that the experiments suggest that gravity as well as magnetism can be transmitted and recorded.

The inventors consider the following concept of thought, the devices according to the invention being referred to as "heavy resonators":
A gravity resonator is a technical device which serves to receive a defined but previously unknown wave of a particle stream or radiation, the strength and time course of which it registers in such a way that it converts this wave, the particle stream or the radiation into a change in weight, which can be registered and read on a highly sensitive scale or by changing a weight-sensitive electrical resistance. The previously unknown wave, the particle flow or the radiation, which is simply referred to here as the "gravity wave", can therefore be received in the resonator claimed according to the invention because, due to its glass-like molecular lattice and or its crystalline structure as an electrical non-conductor, it is able to do so with to resonate with this "gravity wave" coming from the room and to convert it into a particle oscillation, which appears as an increase in density and thus with the same volume of gravity and can thus be registered and measured. Just as more or less dense masses are usually characterized and registered by scales or other devices by their weight.

A heavy resonator thus exists in the simplest case from a glassy or crystalline solid in Shape of a plate, a sphere, a cone or a mixed shape, the hanging or standing connected to the device registering the gravity is so that the received wave as a change in the Severity can be received and registered.

• – muß er als Schwingkreis arbeiten können, d.h. daß in seiner Struktur kapazitive und induktive Elemente vorhanden sind, die einmal erregt diese Schwingung solange bewahren können, daß sie in resonanter Abstimmung zum Empfang der "Schwerewelle", in der Lage sind.
• – ist eine erste Erregung notwendig, welche mittels Hochspannung von 5 bis 20 kV und etwa 0,1 bis 10 μA bei gleichzeitiger Drehbewegung erfolgt. Dabei werden die mikroskopischen Verschaltungen zum Schwingkreis innerhalb des Glas und oder Kristallkörpers ausgerichtet und gleichzeitig erregt, so daß sie danach zur Aufnahme der spezifischen "Schwerewelle" bereit werden.

So that the resonator is ready to receive,

• - He must be able to work as a resonant circuit, that is to say that there are capacitive and inductive elements in his structure which, once excited, can maintain this oscillation for so long that they are able to receive the "gravity wave" in resonant coordination.
• - A first excitation is necessary, which takes place by means of high voltage of 5 to 20 kV and about 0.1 to 10 μA with simultaneous rotary movement. The microscopic connections to the resonant circuit within the glass and or crystal body are aligned and excited at the same time, so that they are then ready to receive the specific "gravity wave".

For a better understanding, the comparison with the magnetism is obvious, in which also a certain material Requirement, namely the orientation of certain crystal regions must be given before the actual magnetization can take place in turn as a result of an inductively generated magnetic field occurs.

The crystalline requirements for the Occurrence of molecular resonant circuits within glassy and or crystalline solid appear in very many both occurring in nature as well artificially obtained To be given non-conductors, especially in organic and inorganic glass as well as quartz and silicate-containing rocks, as well as in carbonates and phosphates, sulfides and halides, especially also in silicate Mixed oxides of aluminum, magnesium, beryllium, titanium and iron, those in the granites, gneisses and other primeval rocks in serpentine and serpentinites never only alone, but always in mixtures occurrence. All of these rocks, minerals and glasses are common that they Own heaviness.

Heaviness must therefore be a substance property are considered with an as yet unknown requirement in the area the atomic or subatomic level. Only then can it actually determining factor for the resonance that occurs in such non-conductors with as always type "gravity wave". The fact, that specific heavier substances react better with the same composition as lighter fabrics shows that this Thought must be correct. This is how lead-containing glasses can be made stronger excite as not containing lead, which shows that heaviness is not just one Measurand is but that there is more to the weight than substance property than before was accepted.

Completely surprisingly can both the effect of becoming heavier and becoming lighter by such claimed according to the invention Resonators can be realized like the experiments described above demonstrate. This is in complete Contradiction to the current teaching, but is in perfect agreement with the view also represented by the inventors, that of the Swiss physicist Oliver Crane in 1992 under the title: Central Oscillator and space quantum medium in the Universal Expert Publishing House, Rapperswil, has been described.

Claims (23)

Device for receiving, transmitting and / or storing at least a portion of the energy of waves with a first body made of non-conductive material, a second body made of non-conductive material and a layer of electrically conductive material between the two bodies of electrical current-non-conductive material is arranged, the opposite sides of the body of electrical current-non-conductive material and the intermediate layer of electrical current-conductive material having corresponding or identical surface contours. Apparatus according to claim 1, which a further or several more bodies has material that is not conductive from electric current. The device of claim 2, wherein the body is made of directly adjoin electrical current of non-conductive material. Device according to one of claims 2 to 3, wherein between bodies made of electrical current non-conductive material layers of electrical Electrically conductive material are arranged. Device according to one of the preceding claims, the corresponding surface contours are flat surfaces. Device according to one of the preceding claims, the the body plates made of electrical current are not conductive material. Apparatus according to claim 6, wherein the plates are plane-parallel. Device according to one of the preceding claims, the the body a round, circular, non-conductive material have an angular, rectangular or square cross-section. Device according to one of the preceding claims, the material that does not conduct electricity is glass, ceramics or crystal. Device according to one of the preceding claims, the material that does not conduct electricity or is organic or inorganic glass, quartz, silicate rock, oxide ceramics, Aluminum oxide, titanium oxide, granite, Kneis, serpentine, serpentinite, PVC, marble, acrylic glass, soapstone and / or steatite. Device according to one of the preceding claims, the the body made of electrical current non-conductive material of the same material or different materials are formed. Device according to one of the preceding claims, of the layers that conduct electricity or metal mesh. Device according to one of the preceding claims, the material conducting the electrical current is copper, iron, graphite, Includes carbon fibers, steel, V2A and / or V4A. Device according to one of claims 2 to 13, wherein the Layers of electrical current conducting material from the same or different material are formed. Device according to one of the preceding claims, which is a polyimide film, PE film, PP film and / or another insulating film between a body of electric current non-conductive material and the layer of electric current conductive material is provided. Device according to one of the preceding claims, the multiple polyimide films, PE films, PP films and / or others insulating film between electrical current non-conductive material and electrical current-conducting material are provided. Device according to one of the preceding claims, the the body made of electrical current non-conductive material 2 to 50 mm, preferably 4 to 20, and in particular 5 to 10 mm thick. Device according to one of the preceding claims, the material conducting the layer of electrical current 0.05 to 1 mm, preferably 0.01 to 0.5 mm thick. Apparatus according to any one of the preceding claims, wherein the layer of electrically conductive material comprises a copper mesh, the copper wires being about 0.5 mm thick and the fabric has a mesh size of approximately 1 mm. Device according to one of the preceding claims or Device for receiving, sending and / or storing at least one Share of the energy from waves with a first body electrical current non-conductive material, and a layer of electrical Electrically conductive material, the device by applying a high DC voltage at a distance from the first body Electrodes or by approaching has been excited to an already excited device. 22. The apparatus of claim 21, wherein the high DC voltage 5 to 20 kV. Apparatus according to claim 20 or 21, wherein the high DC voltage for a few minutes to a few hours or the approach the device already excited for a few minutes to a few hours took place. Device according to one of claims 20 to 22, wherein the The distance between the electrodes during excitation was a few millimeters or when the device is excited, the distance between the exciting and the excited device zero to a few millimeters scam.