WO2011120116A1

WO2011120116A1 - Continuous flow hydraulic energy generator

Info

Publication number: WO2011120116A1
Application number: PCT/BR2011/000084
Authority: WO
Inventors: José Luís TAVARES BRANCO
Original assignee: Tavares Branco Jose Luis
Priority date: 2010-03-30
Filing date: 2011-03-22
Publication date: 2011-10-06
Also published as: BRPI1000863A2

Abstract

The present invention relates to an electric energy generator which, by means of a continuous pipe that is suitably molded and folded and works together with the force of gravity, creates a continuous flow of liquids that move a generator assembly (turbine/d.c. generator). It is characterised in that it achieves the same energy generation capabilities of large hydroelectric and nuclear power plants, but is 100% clean with "zero emissions", requiring no gigantic reservoirs or materials that are hazardous to health, not to speak of burning fuels.

Description

"CONTINUOUS FLOW HYDRAULIC POWER GENERATOR".

The present invention relates to an electric power generator which by means of a continuous pipe, shaped and bent properly and acting in conjunction with the force of gravity, creates a continuous flow of liquids by moving a generator set (turbine / dynamo ).

In the energy sector today we have some power generation options that are capable of generating from small to large demands, thereby meeting the needs of modern life, but all existing sources are either polluting or have high implementation costs or devastate the environment where they are built.

Among the existing options (hydroelectric, wind, solar, nuclear, thermoelectric, etc.), there is a need for a high-power generator that can replace or assist existing ones and supply the increased demand that is imposed on almost everyone today. developed countries in a clean, environmentally friendly, economically viable and sustainable manner.

This invention will be an alternative to such current polluting sources of energy generation, based on fossil fuels, non-renewable sources, energy from radioactive sources and reservoir-based sources in artificially created large lakes, with the aim of eliminating harmful emissions to the environment and the environmental impacts from large constructions still needed today.

The present invention has as its main advantage the generation of electricity with the same capacity as large hydroelectric plants, but without the need for gigantic reservoirs, since it works with a limited amount of liquids that are continuously reused or captures and returns the same amount of liquid. sources of running water such as rivers and seas. Similarly, by varying the size of the equipment, the inventive process is also capable of solving medium and small energy demands. This invention is also characterized by being environmentally clean, since energy is generated without the emission of pollutants in its generation process (Zero Emissions).

The Continuous Flow Hydraulic Power Generator can be used in virtually all types of environments: from open environments such as seas, rivers, lakes or open terrain, using equipment support platforms and structures, to indoor environments such as homes, buildings. , industries, ships, vehicles, etc., using the building structure itself in the environment to assemble the equipment, needing only a small reservoir to operate it and a pipe distribution suitable for the existing construction, all at a low cost. more than satisfactory for the inherent needs.

The inventive principle is that a liquid within an appropriately bent and continuously molded continuous pipe which, once uprighted, will expose its contents to the action of the force of gravity and it will have permanent movement after the equipment is operated.

This invention consists of a suitably shaped, bent, vertical, horizontal and inclined straight pipe that mates with a generator set (turbine / dynamo), whether or not attached to a support and support structure and a liquid source ( reservoirs, seas, rivers, lagoons, etc.) acting in conjunction with the force of gravity, will provide movement to the liquid inside the pipe, which in turn will move the generator set, resulting in the electrical power.

We divide this tube into two sections (1) and (2) as seen in Figure 1, and we will call them up and down respectively, knowing that section (1) will be shorter in length than section (2).

The ascending section (1) begins at reservoir level (8) or running water source (rivers, seas, lakes) with its inlet mouth (5) being in permanent contact with the liquid contained therein, where thereafter the piping will ascend vertically to a predetermined height, bending and beginning the descending section (2).

The descending section (2) in turn begins immediately after the final folding of the ascending section (1) at the highest height of the equipment, taking from there shapes that may vary from spirals, angular "come and go" configurations, S or Z and other sequences, coming close to the reservoir level where it connects to the generator set (3) (Turbine / Dynamo) that is installed at that level and in turn at its outlet (6), will pour the liquid back to the reservoir (8) from which it began.

Before the equipment can be started, the following sequence of actions must be taken:

1 . Close the pipe inlet (5) and outlet (4) gates.

2. Fill upstream (1) and downstream (2) completely with liquid using the liquid inlet valve (7) coupled to a standard water pump.

3. Close the liquid inlet valve (7) completely by sealing the system.

4. Simultaneously open the inlet (5) and outlet (4) gates.

Once this is done the liquid contained in the downward section (2) of the pipe which by having a volume much larger than that contained in the upward section (1) by the action of gravity will flow through the outlet mouth (6) which in turn will act with suction force in the liquid contained in the pipe section (1), causing all liquid contained in the pipe (1) and (2) to flow continuously through the outlet (4) which will pass through the generator set (3 ) and finally returned to the reservoir (8) or source of running water by the outlet pipe (6).

The continuous pipe (1) and (2) can be formed by pipes, tubes or hoses, the material of which can be steel, aluminum, concrete, PVC, acrylic, iron, etc. to be defined at the best convenience of environment and design. The piping may not be restricted to a single continuous pipe, but may also be made for better space utilization and higher power through the use of parallel and multiple pipes as seen in figure 2.

The longer section (2) of the pipe compared to section (1) the more force and power the equipment will be able to generate.

The equipment must have a liquid inlet valve (7) connected by extra piping connected to a common type water pump for the initial phase of the pipeline filling process.

The equipment must also have gates or valves for opening and closing the inlet (5) and pipe outlet (4), which will act in the filling phase of the pipes so that the equipment or section can be triggered in cases. shutdown is required.

Depending on the location of the application and the model to be used it may be necessary to use external support and fixation structures of the equipment, such as mounting the equipment at sea or in a lake, it is necessary to include a platform that will keep the equipment above liquid level. Already in a residence or building, the building itself serves as a support base for the necessary pipes and equipment.

With regard to the generator set (3) we have the possibility of installing it externally, which is close to the level of the reservoir (8) coupled to the pipe immediately after its outlet (4), and internally, installed internally along the piping using several smaller sets of dynamos-connected turbines or spinning propellers that can work submerged in liquids by passing the outlet (4) to return the liquid directly to the reservoir.

A first embodiment of the equipment seen in Figure 1 is a straight vertical pipe (1) having its inlet mouth (5) immersed in a reservoir filled with liquid and thereafter rising vertically to a predetermined height, where it will bend and will start a descent in the form of spiral (2) that will surround this vertical pipe until it approaches the liquid level where the generator set (3) will be and will be coupled therein. Finally at the outlet of the generator set we have a new pipe (6) that only directs the liquid back to the reservoir.

A second embodiment of the equipment seen in FIG. 2 is a straight vertical pipe (1) having its inlet nozzle immersed in a liquid-filled reservoir (5) and from there it will rise vertically to a predetermined height, where it will bend and it will start a back and forth descent (2) or S-shape parallel and perpendicular to the vertical piping until it approaches the level of the reservoir where the generator set (3) will be and will engage at its inlet. Finally at the outlet of the generator set we have a new pipe (6) that only directs the liquid back to the reservoir.

A third model of the equipment seen in Figure 3 is to connect in series several up and down sets based on the models described above, in order to obtain a single pipe that joins them all into a single set with several ascending sections (1 ) and descendants (2), in this case installing the inlet mouth (5) which contacts the liquid in the first assembly in its upward section (1) and the generator set (3) in the outlet mouth (4) of the latter. together in its descending section (2) thus obtaining a equipment several times more potent because we have a volume of liquid subject to the forces of gravity several times greater.

Claims

1. Continuous Flow Hydraulic Power Generator consisting of properly formed and folded up (1) and down (2) continuous piping that acting in conjunction with the force of gravity creates a continuous flow of liquids by moving a generator set (3) (turbine / dynamo).

Generator according to Claim 1, characterized in that it is pipe-shaped equipment whose inlet mouth (5) will be in contact with a liquid in a reservoir (8) or a source of running water (rivers, seas, lakes).

Generator according to Claims 1 and 2, characterized in that the rising pipe (1) rises vertically to a desired height.

Generator according to Claims 1 to 3, characterized in that the rising pipe (1) is bent towards the ground after reaching the desired height.

Generator according to any one of claims 1 to 4, characterized in that the pipe after bending begins to descend taking the most varied forms, obeying the rule that the total length of the descending part (2) will be greater than the total length of the pipe. ascending part (1).

Generator according to Claim 5, characterized in that the downstream piping (2) may take various forms. Examples: Spiral-shaped strings, S-shaped strings, Z-shaped strings, Mixed-format strings (mixtures of different shapes), etc.

Generator according to Claims 5 and 6, characterized in that the downstream piping at its outlet port (4) feeds the inlet port of a generator assembly (3) (turbine / dynamo).

Generator according to Claim 7, characterized in that the outlet of the generator assembly (6) pours the liquid back into the reservoir (8) or the source of running water (rivers, seas, lakes) where it was initially captured.

Generator according to Claims 1 to 8, characterized in that there is a liquid inlet valve (7) at the top of the pipe, connected to a common water pump for the initial filling of the pipes.

Generator according to Claims 1 to 9, characterized in that at the beginning and end of the pipeline there are gates or valves for opening and closing the inlet (5) and outlet (4) mouths.

1 1. Generator according to claims 9 and 10, characterized in that the inlets (5) and outlet (4) are closed to initiate the filling of the pipe or to stop the operation of the equipment.

Generator according to Claims 9 to 11, characterized in that the inlets (5) and outlet (4) are open at the end of filling, thus starting the equipment.

Generator according to Claims 1 to 12, characterized in that there is a need for external support and fixing structures for pipes and equipment.

Generator according to Claims 1 to 13, characterized in that multiple pipes may be used to obtain power. According to figure 2.

Generator according to Claims 1 to 14, characterized in that a number of up and down assemblies can be connected in series which will also bring the equipment to higher power levels. According to figure 3.

Generator according to Claims 1 to 15, characterized in that the generator set (3) can be external (installed at reservoir level) or internal turbines installed inside the pipe.