DE102010008976B4 - Wave engine with synchronized S rotors - Google Patents

Abstract

The invention relates to a wave power machine for collecting and utilizing energy contained in ocean waves, with a plurality of S-rotors which are arranged close to one another and are synchronized in a special way.

Description

The aim of this invention is the capture and utilization of energy contained in ocean waves.

The state of the art is, inter alia, an array of oblong Savonius rotors, which are clamped close to each other in a common frame. Bringing this "rotor array" close to a turbulent water surface, the rotors are rotated by the prevailing orbital flow in rotation. On the rotors a useful power is tapped via suitable converters ( DE 10 2004 060 275 A1 ).

The use of a large number of small rotors instead of a large saves material and weight at the same power and multiplies the rotational speed. Smaller rotors can also use smaller waves and thus a larger spectrum of wave energy. But the rotor array is more than just the sum of its rotors: in the larger flow context, unlike a single rotor, it acts like a wall that can not easily avoid a transverse flow. The water is then forced through between the rotors and thereby accelerated. The faster flow drives the rotors more efficiently.

The present invention now seeks to improve the interaction of adjacent rotors in a rotor array.

The basic element of the improved wave force machine according to the invention is a two-bladed Savonius rotor with a flat S-shaped profile as in FIG 6 , the "S-rotor". Unlike a multi-bladed Savonius rotor, the S-rotor is not a pure drag rotor, but efficiently generates a significant portion of its torque through hydrodynamic lift. Especially when the rotor profile is temporarily aligned along the flow. The concave sides of the rotor blades are here filled streamlined, which at the same time increases the stability of the rotors against the wave force. The rotor blades are essentially rigid here. S-rotors are already known as rotary wings of all sorts of wind toys.

Savonius rotors use a significant portion of the flow energy to cause the surrounding fluid to rotate. This rotational energy is mostly lost for use, which is responsible for the low efficiency of such rotors. In a rotor array, however, the radiated rotational power can affect adjacent rotors and even support them. The latter succeeds according to the invention best when adjacent Savonius rotors rotate in the opposite direction and for this purpose have mirror-image profiles. The rotational flows emanating from the individual rotors now cancel each other out, the energy is retained in the array.

It is state of the art to surround Savonius rotors to improve their efficiency with vanes, which direct the flow on the moving blades in the flow direction or shield the backward rotor blades. In a rotor array, adjacent rotors can take over the function of such vanes when the rotors are properly synchronized. The rotors of the new wave engine are therefore according to the invention coupled by a gear transmission, in such a way that whenever a rotor is aligned in profile along the flow, its respective neighbors are transverse, and vice versa.

More specifically, each rotor alternately performs two different functions as it rotates, depending on its instantaneous position with respect to the flow. The first function is the efficient generation of torque, preferably by hydrodynamic lift with accelerated flow. This happens when the rotor is aligned along the flow. The second function is to support adjacent rotors by redirecting the flow toward them. This happens when the rotor is transverse to the flow. 5 gives it an idea.

The synchronization also makes it possible to choose the rotor distances narrower, which increases the mutual influence of the rotors. In particular, at distances of less than a rotor diameter would occur without a synchronization to the collision of adjacent rotors. The coupling of the rotors also causes a more even course of the torque.

The gear transmission is preferably made of similar gears, at least one on each rotor shaft. They mesh with the gears of the adjacent rotors. The gears must transmit only relatively small forces for synchronization, since all rotors are exposed to a more or less equal flow.

According to the invention, the coupling gears are also part of a gear pump which, as a power converter, collects the powers of the individual rotors and makes them available in the form of hydraulic power. The gears are sealed for this purpose in a common pump housing. The hydraulic fluid used in the simplest case, seawater from the environment, which is guided to avoid fouling or pollution as possible in a closed circuit. The recovered power can be routed through pressure pipes to other locations, power hydraulic machines and power generators, move seawater to higher reservoirs or squeeze it through desalination filters. Gear pumps can in principle produce very high pressures, as they are needed for desalination.

Of course, another power converter can be used instead of the gear pump, in particular an electromechanical converter. Instead of meshing gears, the rotors can also be coupled in other ways, such as a connecting rod or a chain transmission.

The S-rotors are preferably made of an impact-resistant plastic such. As polyethylene. So they are inexpensive and lightweight and are not corroded by salt water. The rotors are most easily built up disk-wise along their axes and held together by tie rods that run inside the rotors. The rotor disks can be z. B. cut with a water jet of plastic plates.

The S rotors rotate on plain bearings around shafts made of seawater-resistant steel. As a plain bearing is sufficient in the simplest case, a hole in the rotor center, lubricated with some grease and ambient water. The axles are clamped from both ends in a stable frame and can therefore withstand high load even with a small diameter.

The gears and other parts of the gear pump are preferably made of plastic. They are, like the rotors, z. B. manufactured as water jet blanks and braced with these.

The drawings are explained in more detail below.

1 shows the heart of the wave engine, namely the array of S rotors ( 1 ) and how these with gears ( 6 ) are coupled. The rotors are rotatable about immovable axes ( 4 ) stored.

2 shows the wave engine in section. The rotors ( 1 ) are with their axes in a frame ( 3 ) clamped. On the rotors a hydraulic pump is mounted, consisting of pump housing ( 7 ) and gears ( 6 ). You can also see a hydraulic connection ( 8th ). The cut surfaces are hatched.

3 shows the wave engine as a whole.

4 shows the sense of rotation of the S rotors in the array. Neighboring rotors have mirror-image profiles.

5 shows a snapshot of the streamlines in a rotor array. Direction and strength of the orbital flow are constantly changing, as well as the rotor positions. Between the rotors, the flow is generally greatly accelerated. This causes a higher speed and a larger torque of the rotors, in any position.

6 shows the profile of an S-rotor. In the middle is the rotor axis ( 4 ). The rotor ( 1 ) is made up of several parts, such as discs, in the axial direction of two tension rods ( 5 ) are held together.

Claims (13)

A wave force machine for collecting and utilizing energy contained in sea waves, comprising a plurality of rotatably mounted flow rotors which are rotated by flow from each direction crossing the respective rotation axis, a transmission which synchronizes the rotational movements of the flow rotors, a support with which the Flow rotors can be positioned at least partially in the orbital flow of water waves, characterized in that each flow rotor in the axial direction is longer than a multiple of its largest diameter, that the axes of rotation of adjacent rotors are substantially parallel, that each flow rotor at least one immediately adjacent flow rotor close to itself has, at an axial distance of at most three of its largest diameter, that each two adjacent flow rotors rotate in the opposite sense that each flow rotor at least in sections, in the course of its rotation and depending on its current position to the flow alternately fulfills two different functions, namely firstly the predominantly efficient generation of torque in a first position, and secondly the primary redirecting of the flow to its immediate neighbors to assist them a second position, that a flow rotor is at least partially in the first position, while its immediate neighbors there are just in the second position, and vice versa. Wave force machine according to claim 1, wherein at least one of the flow rotors has a substantially equal cross-sectional profile everywhere, which may be wound along the axis. Wave force machine according to one of the preceding claims, wherein at least one of the flow rotors has an S-shaped cross-sectional profile. Wave force machine according to one of the preceding claims, wherein the transmission is a gear transmission. A wave force machine according to claim 4, wherein the gear transmission is part of a gear pump. Wave force machine according to claim 5, wherein the gear pump generates pressurized water. A wave force machine according to claim 6, wherein the gear pump presses seawater through a desalination filter. Wave force machine according to one of the preceding claims, wherein it is attached to a floating platform or to a ship's hull. Wave force machine according to one of the preceding claims, wherein at least one flow rotor in the direction of its axis of rotation is composed of discs. Wave engine according to one of the preceding claims, wherein at least one flow rotor, a part of a transmission, or possibly also a part of a pump made of plastic, and preferably made of recycled plastic. Wave engine according to claim 4, wherein instead of the gear transmission another gear is used, in particular a chain drive or a conrod gear. Wave engine according to claim 5, wherein instead of the gear pump another power converter is used, in particular an electromechanical transducer. Wave force machine according to one of the preceding claims, wherein this is also or exclusively driven by a different flow, as of the orbital flow of the sea waves, in particular of a tidal current, or in other fluid than water.

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