FR3044721A1 - HYDRAULIAN WITH VERTICAL AXIS AND FREE SWIVEL BLADES ENTIRELY IMMERED IN CURRENT WATER, AND THAT PRODUCES ELECTRICITY, NAMED K3 - Google Patents

Abstract

The present invention relates to a hydraulic axis with vertical axis and free rotating blades, fully immersed in water with a current, a river, a river or marine currents, and which produces electricity, called K3. The device comprises four blades of flat surfaces and rotating on their own vertical axis, these being arranged between a low support and a high support, at regular intervals of 90 ° around the vertical axis of the hydraulic. Each blade can rotate 180 ° on its own vertical axis, under the thrust of the current. Consider the hydraulic view from the front. The corant grows uniformly on all the hydraulienne. The blade on the right side of the vertical axis of the hydraulic comes in abutment and offers its total surface perpendicular to the current. The blade on the left side of the vertical axis is parallel to the direction of the current because it has a possibility to turn 180 ° on its own axis. As it is parallel to the current, it offers no support surface for the force of the current. The force of the current which pushes on the right blade thus makes turn the hydraulienne. After 90 ° rotation of the hydraulic, two new blades are present. As described above, the right vane rotating on its own axis abuts and offers its total surface perpendicular to the current. The left blade pivots on its own axis and out of the current paralleling the current. The hydraulic continues to rotate. An electric dynamo is attached to the mast. It produces electricity when the hydraulics rotate.

Description

The present invention relates to a hydraulic axis with vertical axis and free rotating blades, fully immersed in water with a current, a river, a river or marine currents, and which produces electricity, called K3.

Existing hydraulics are equipped with a horizontal axis propeller.

The device according to the invention comprises four blades of flat and rotating surfaces on their own vertical axis, these being arranged between a low support and a high support, at regular intervals of 90 ° around the vertical axis of the hydraulic . Each blade can rotate 180 ° on its own vertical axis, under the thrust of the current. Consider the hydraulic view from the front. The current grows uniformly over the entire hydraulics. The blade on the right side of the vertical axis of the hydraulic comes in abutment and offers its total surface perpendicular to the current. The blade on the left side of the vertical axis is parallel to the direction of the current because it has a possibility to turn 180 ° on its own axis. As it is parallel to the current, it offers no support surface for the force of the current. The force of the current which pushes on the right blade thus makes turn the hydraulienne. After 90 ° rotation of the hydraulic, two new blades are present. As described above, the right vane rotating on its own axis abuts and offers its total surface perpendicular to the current. The left blade pivots on its own axis and out of the current paralleling the current. The hydraulic continues to rotate. An electric dynamo is attached to the mast. It produces electricity when the hydraulics rotate.

A cage with a fine mesh can be fixed around the hydraulics to prevent the fish from getting into the blades.

Operation of the hydraulic according to Figures 1 and 2, which represent in schematic top views, the device in two phases of rotation of the hydraulic.

Figure 1: position of the blade (A) perpendicular to the direction of the current. This blade offers its maximum surface and orthogonal to the current. As a result, she turns the water pump. The blades (B), (C) and (D) are oriented parallel to the direction of the current.

Figure 2: The hydraulic turned 45 ° around the mast compared to Figure 1, under the influence of the current. The blade (A) always exposes a large area to the force of the current. She turns the hydraulics. The blade (D) is now also oriented to provide its surface current, fully against its stop. The blade (B) which was in abutment is now outside the reach of its stop. She turns on her gons under the effect of the current which pushes her backwards, and she is placed parallel to the current. Thus the blades (B) and (C) turn on their gons and parallel to the current, and float like flags in the current, the hydraulic continues to rotate.

According to particular embodiments: the hydraulic can comprise 2, 3, 4, 5 or more rotating blades. - The height of the hydraulics can vary from 0.20 to 10 m. - The axes of the rotating blades can be made with ball bearings.

The accompanying drawings illustrate the invention:

Figures 1 and 2 show schematic top views, the device in two phases of rotation of the hydraulic. The operation is described above according to these two figures.

Figure 3 shows an elevational sectional view of the device, all the blades resting against their stops.

Figure 4 shows the section A-A of the device, or so to say the plan view.

Referring to Figures 3 and 4, the device comprises a vertical mast (1) made of steel tube diameter 21.5 mm which is sealed in a concrete foundation (2). The edge of the foundation is beveled so that fish seeking food by scraping the bottom of the river are stuck and hunted, and do not climb into the blades.

A low support (3) and a top support (4) of plywood 12 mm thick in the form of a circle each contain a ball bearing (5) of inner diameter 25 mm which is sealed at their center. These low supports (3) and high (4) are rigidly interconnected by a PVC tube diameter 50 mm (6) which will take the weight and especially the torsion forces from the hydraulic. An amount (7) in the form of a stem and very solid connects the top of the axis to its foot at the foundation. Below the low support (3) is fixed a round wooden coaching plate (8) of thickness 40 mm which will cause the roller of the dynamo (9). These elements above form the support of the rotating body of the hydraulic.

The 6 volt dynamo (9) is fixed to the mast by a steel arm (10).

When the body of the hydraulic rotates under the effect of the current, the driving plate (8) which is integral causes the roller of the dynamo (9) which will rotate and produce electricity.

Four blades (11) of flat plywood surface 4 mm thick are fixed on the low supports (3) and high (4) by gons (12). These four blades can rotate on their own vertical axis, but they are limited to 180 ° in rotation by the stops (13) fixed on the low supports (3) and high (4) and on the tube (6). The stops (13) are rubberized in order to damp the shocks of the blades. A cage (14) completely encloses the hydraulienne in order to discard the fish.

Claims (1)

1) Hydraulic vertical axis characterized in that it comprises four blades of flat surfaces and rotatable on their own vertical axis, the latter being arranged between a low support and a high support, at regular intervals of 90 ° around the vertical axis of the hydraulic. Each blade can rotate 180 ° on its own vertical axis, under the thrust of the current. Consider the water front view. The current grows uniformly over the entire hydraulics. The blade on the right side of the vertical axis of the hydraulic comes in abutment and offers its total surface perpendicular to the current. The blade on the left side of the vertical axis is parallel to the direction of the current because it has a possibility to turn 180 ° on its own axis. As it is parallel to the current, it offers no support surface for the force of the current. The force of the current which pushes on the right blade thus makes turn the hydraulienne. After 90 ° rotation of the hydraulic, two new blades are present. As described above, the right vane rotating on its own axis abuts and offers its total surface perpendicular to the current. The left blade pivots on its own axis and out of the current paralleling the current. The hydraulic continues to rotate. An electric dynamo is attached to the mast. It produces electricity when the hydraulics rotate.