WO2019136534A1 - Hydro-archimedean engine - Google Patents

Abstract

The aim of the present invention is to create a device for autonomously generating a constant imbalance and an evenly accelerating motion in static and dynamic systems. The problem of interest is solved using a device disposed within a gravitational field, said device consisting of one or several large symmetrical annular rotors disposed in a closed chamber; a rotor has a rotating shaft that is disposed horizontally through the geometric center of the rotor profile; the closed chamber is vertically divided into two parts by dividing frames; the first part of the closed chamber is filled with a liquid and is sealed; the second part of the closed chamber is filled with a vacuum, air, or a liquid that is less dense than the liquid in the first chamber; one part of the rotor is disposed in the first part of the closed chamber; the remaining part of the rotor is disposed in the second part of the closed chamber.

Description

 Hydro-Archimedean Engine

 Technical field

The device can be used to create a stable imbalance, to create equal-accelerating motion and to generate energy.

Current state

The existence of previous devices with a similar operating principle is unknown.

SUMMARY OF THE INVENTION

The aim of the present invention is to provide a device for the autonomous generation of stable imbalance and equal-accelerating motion in static and dynamic systems.

The task is performed by a device located in a gravitational field, which consists of:

 volume rotor with a random circular symmetrical shape located in a closed chamber;

 - the rotor has an axis of rotation located horizontally through the geometric center of its profile;

 - the closed chamber is divided vertically into two parts by one or more dividing frames;

 - the first part of the closed chamber is filled with liquid and can be hermetically or non-hermetically closed;

- the second part of the closed chamber is filled with vacuum, air, or liquid with a lower density of liquid in the first chamber and can be either hermetically sealed or non-sealed; - one part of the rotor is located in the first part of the closed chamber;

 - the rest of the rotor is located in the second part of the closed chamber;

 - the dividing frame is in close contact with a low degree of friction with the rotor;

In one example, the axis of rotation of the rotor is mounted on both sides to the wall of the closed chamber.

In another example, the axis of rotation of the rotor is located on the support rollers.

In one example, the rotor has a spherical shape, and a vertical separation frame is constructed by applying sheets of flexible film that is tightly attached to the camera on one side and tightly pressed against the rotor with an elastic band in the annular region, in the entire circumference of the rotor.

In another example, the separation frame is made of overlapping sheets of a flexible film, which is metal, polymer or textile, a low coefficient of friction that is tightly (tightly) attached to the cell wall and / or stretched with elastic bandages or with spring links or using counterweights or using magnetic forces or electrostatic forces; or the frame is made of a ring of insoluble bulk gel, paste or grease with a low coefficient of friction, or a combination of one or more of the above elements.

In another example, a bulky rotor in the form of a toroid with a round cross section, the closed chamber is divided into two chambers of tightly adhered permanent magnets coated with ferrofluid, which is tightly in contact in two annular zones in the vertical section of the rotor. In another example, the rotor is connected via a transmission belt to a transmission from which the axis gear is output. An adjustable spindle shaft mounted in a housing with inlet and outlet openings is attached to the pinion gear. At the output of the shaft there is a flexible tube with a rigid nozzle. The nozzles are attached to an adjacent removable panel on the second part of the closed chamber, movably clamped to its upper side to the axis, and waterproofed with a flexible membrane.

Description of drawings

Figure 1 shows a three-dimensional perspective view of a mechanism with a spherical rotor and a foil frame.

 Figure 2 shows a three-dimensional perspective view of a mechanism with a toroidal rotor, with a frame made of ferromagnets and ferrofluid, with external support rollers, with transmission and with an adjustment mechanism.

Implementation examples

Figure 1 shows an example of a device in accordance with the present invention. A device located in a gravitational field consists of a spherical rotor (1). The rotor is located halfway in the first part (7) of the closed chamber (2) containing water and penetrates the second part of the closed chamber (not shown) through a vertical separation frame (3) made of overlapping sheets of flexible film that is on one side hermetically attached to the chamber, and on the other hand is tightened with an elastic bandage (4) so as to ensure tight (moisture-proof) contact in the annular region around the circumference of the rotor (1), including in the case of fluctuations during rotation. The rotor (1) is located on the axis of rotation (5), passing horizontally through the geometric center of its profile and attached on both sides to the wall of the chamber (2). In its working process, the rotor part (1), which is located in the volume of the first part (7) of the chamber (2), undergoes hydrodynamic lifting force (the so-called “Archimedes force”), in contrast to the other part of the rotor. This leads to a stable imbalance along the axis of rotation (5) and, thus, gives a constant uniform acceleration of rotation of the rotor (1), without changing the volume occupied by it inside the first part (7) of the chamber (2). The generated uniformly accelerating rotation continues until it is stopped with the application of an external force; or until the separation frame (3) is redirected to a horizontal position; or until the pressure of the separated substances on both sides of the separation frame (3) is equalized; or until the whole mechanism is removed from the gravitational field in a weightless state; or until the achieved acceleration exceeds the mechanical strength of the mechanism.

Figure 2 shows another example of a device in accordance with the present invention. A device located in a gravitational field consists of a toroidal rotor with a circular cross section (1); into the inside of the closed chamber (2); and passing through two separation frames (3) made of tightly selected permanent magnets (20) coated with ferrofluid (19), which provide strong (hydronically tight) contact in two annular zones in the vertical section of the rotor (1), including in case of oscillations at its rotation. The rotor (1) is supported on both sides by support rollers (6). The first part (7) of the chamber (2), formed by the separation of the chamber (2) from the frame (3), contains a vacuum and is hermetically closed, and the second chamber (8) contains flowing mercury and is not hermetically closed, and because of the chamber (2) and frames (3), the fluids used cannot be dispersed and mixed with each other or with the external environment. The rotor (1) is connected to the transmission belt (9) with a transmission (10), from which the axial gear (11) comes out, which removes energy from the rotor for external use. The drive shaft (12) located in the housing (13) with input and output holes is rigidly connected to the transmission axis, and the flexible tube (14) with a rigid nozzle (15) attached to the outlet. The nozzle (15) is rigidly attached to an adjacent flexible panel (16) of the second part of the chamber (8), which movably engages its upper side of the axis (17) and is waterproofed with a flexible membrane (18).

In its working process, part of the rotor (1) in the volume of the second part (8) of the chambers (2) experiences a high hydrodynamic lifting force (the so-called “Archimedes force”), which leads to a high stable imbalance and creates a high constant uniform acceleration of rotation of the rotor ( 1), without changing the volume occupied by the rotor (1) into two parts (7) and (8) of the chamber (2), thanks to the support provided by the rollers (6). The rotation of the rotor (1) is transmitted for use outside the mechanism through the belt (9) through the transmission (10) to the axial gear (11). At the same time, a small part of the movement is transmitted to the control blade shaft (12), which generates a proportional fluid flow through the pipe (14) to the nozzle (15), in which the proportional pressure of the movable insulated panel (16) is. In case of exceeding a certain critical threshold of the rotor speed (1), the panel (16) is shifted around the axis (17), thereby increasing the volume of the second part (8) of the chamber (2), which leads to a decrease in the level of mercury in it and, accordingly, a decrease in the rotation force rotor (1); when the rotation speed of the rotor (1) falls below a critical threshold, the panel (16) returns to its original position under the influence of its weight. The generated uniformly accelerating rotation continues until it is stopped with the application of an external force; or until the separation frame (3) is redirected to a horizontal position; or until the pressure of the separated substances on both sides of the separation frame (3) is equalized; or until the whole mechanism is removed from the gravitational field in a weightless state; or until the achieved acceleration exceeds the mechanical strength of the mechanism.

Application of the invention The invention is applicable to all areas of local and autonomous energy generators and offers an effective alternative to all types of existing combustion sources or renewable energy sources. The only condition for its functioning is the presence of significant gravity, which is immediately and unlimitedly available everywhere on the surface and inside our planet, as well as on other planetary cosmic bodies. Due to its simple design and widely available materials for mass production, the invention has an advantage over all types of existing energy generators, as well as compared to other possible mechanisms of absorption of gravitational energy. In addition, its print type of work allows you to generate a very large power with low weight and, accordingly, low dead weight of the mechanisms used.

Claims

Claims

1. A device for autonomous generation of stable imbalance and equal-accelerating motion in static and dynamic systems located in a gravitational field, containing:

 - one or more volumetric annular symmetrical rotors (1) located in a closed chamber (2);

 - the rotor (1) has an axis of rotation (5) located horizontally through the geometric center of its profile, fixed on both sides to the wall of the closed chamber (2), or located on the support rollers (6);

 - the closed chamber (2) is vertically divided into two parts (7) and (8) with one or two dividing frames (3);

 - the first part (7) of the closed chamber (2) is filled with liquid and may be airtight or leaky;

the second part (8) of the closed chamber (2) is filled with vacuum, air or liquid with a lower density of liquid in the first chamber and can be either hermetically closed or not hermetically closed;

 - one part of the rotor (1) is located in the first part (7) of the closed chamber (2);

- the rest of the rotor (1) is located in the second part (8) of the closed chamber

(2);

 - the dividing frame (3) has a tight contact with a low coefficient of friction with the rotor (1).

2. The device according to claim 1, characterized in that the rotor (1) has a spherical shape, and the vertical separation frame (3) is made of overlapping sheets of elastic foil, which are sealed on one side to the chamber (2), and on the other hand tightly fastened with an elastic bandage (4) in the annular region around the entire circumference of the rotor (1).

3. Device according to any one of the preceding paragraphs, characterized in that the dividing frame (3) is made of overlapping sheets of elastic foil, metal, polymer or textile, with a low coefficient of friction, which is tightly closed to the chamber wall (2) and / or tightened with elastic bandages, or spring links, or using counterweights, or using magnetic forces, or electrostatic forces; or the frame (3) is formed from a framework of an insoluble bulk gel, paste or low friction lubricant; or a combination of one or more of the listed elements.

4. The device according to claim 1, characterized in that the rotor (1) is a toroidal rotor with a circular cross section, and the closed chamber (2) is separated by two divided frames (3).

5. A device according to claim 1 and 4, characterized in that the dividing frames (3) are made of tightly mounted permanent magnets (20) coated with ferrofluid (19), which are tightly in contact in two annular zones along the vertical part of the rotor (1).

6. The device according to claims 1, 4 and 5, characterized in that the rotor (1) is connected via a transmission tape (9) to a transmission (10), from which an axial gear (11) comes out, to which the spindle shaft (12) is fixedly connected ) installed in the housing (13) with inlet and outlet openings, a flexible tube (14) with a rigid nozzle (15); the nozzle (15) is fixedly attached to the adjacent movable panel (16) of the second part (8) of the closed chamber (2), which is movably attached from above to its axis (17), and is waterproofed with a flexible membrane (18).