CH702901A2 - Power station e.g. tidal power station, for generating electricity, has rotary piston engine with stroke chamber, where water flows through openings of stroke chamber and another chamber, and low pressure is produced in latter chamber - Google Patents

Abstract

The station has a rotary piston engine (48) with a stroke chamber having an opening, where water flows through the opening and another opening in a chamber separated from an inlet. The engine has a rotary piston drawn along length of an axis of rotation, and low pressure is produced in the latter chamber. A feeding hopper (50) and a housing are arranged in an engine housing for guiding the flow of water through inlet openings (49) in the piston, where the piston is rotated and aligned based on geometry of the housings. Breadth and height of the engine are 50 cm. An independent claim is also included for a method for constructing a power station.

Description

The present invention relates to a method for driving by means of flow and hydraulic pressure along the axis of rotation drawn in the length rotary piston, which in turn drives a generator for generating electricity.

The advantage of the present invention is that very low pressures in the kinetic energy is converted by the large piston areas can be produced cheaply and thus economically despite small system energy electricity is generated.

As a particularly suitable design of such motors as an expansion machine or clocked turbomachine is the principle of Wankel engine. Due to the very short crankshaft in relation to the piston surface, powerful, fast rotary motion can be generated even at very low pressure. In addition to the well-known ratio in the internal combustion engine of 2/3 of the toothing of the gear on the housing and the inner ring gear on the piston even rounder, polygonal designs with smaller ratios x / x + 1 are particularly advantageous. It turns a polygon within a housing which has a length less than the polygon. For example, in the ratio 2/3 of the classical Wankel, this corresponds to a triangle in 2 trochoidal arches and 4/5 to a pentagon in 4 trochoidal arches as a cross.

In a particularly round design can be dispensed with the guide gears, because the piston moves along the housing contour. It is important to ensure the best possible sliding property.

Due to the rotary piston geometry according to Wankel, several piston surfaces can be acted upon by force, pressure or negative pressure at the same time, which generates a very high torque with small oscillating mass. Virtually around the axis of rotation forces and moments act in the direction of the rotational movement.

The fluid flow goes in one direction and by the rotational movement, the piston chambers are each charged again without having to perform a backward movement as is the case with the reciprocating.

The flow is captured by means of a vessel, advantageously by means of a funnel and passed through slots radially to the axis of rotation on the rotary piston. The funnel may be tapered, or it may consist of a tube with a parallel partition between the inlet and outlet slots and a tapered partition between the outlet slot and the next inlet. This creates in each case a piston chamber acting equally on both sides funnel.

The ratio of the inlet openings to the funnel tube size is adjusted with the length of the engine. When used as a tidal power plant or at a level difference, one side can also be designed to be open and the other side to the different level to be executed closed.

With the length of the engine, the piston surface is influenced, at which pressure the starting torque is overcome. With a surface area of several square meters, a few millibars are enough to start the engine.

This property is particularly advantageous when used in tidal power plants which should work as small as 1 bar, even at a small differential pressure. With a piston of one meter in diameter and 5 meters in length, which is pressurized in half, results in a difference in height of the water level between an inlet and outlet of 1 cm, at 0.01 bar a compressive force of about 800 N. At 10 cm it is already about a ton.

The piston diameter, the height and width of the piston should be greater than 50 cm and in length more than 60 cm, with an upper limit of several meters in width height and in length.

Although smaller engines are also functional, but relatively uneconomical respectively useful for special purposes.

In order to avoid contamination and blockages is derived by means of a grid or grate oncoming Good.

To dispose of a small amount of force in the oscillating mass of the piston as possible with the same density as the environment has executed. A weight, density difference of 60% should not be exceeded. This can be done with the choice of materials, air chambers or floats.

In the underwater constructions of today known systems accounts for a large part of the cost of the, attachment and orientation to the flow. In this technology described with this patent, the first mentioned variant, can be solved easily and very cheaply by the construction, usually the housing is made floating and the construction is anchored with a rope to the ground. The construction must have at least as much lift that the flow that drives the rotary piston can not press the structure due to the tensioned rope on the ground.

If feet mounted on the housing, less buoyancy can be selected, respectively, be waived if the construction should make no rotational movement in an alternating flow direction.

The rope or other type of attachment is mounted between the center of gravity and the inlet opening. As a result, the elongated structure rotates in each case with the flow so that the inlet opening is normal to the flow, thereby ensuring an optimal inlet.

The combination of buoyancy, attachment point (s) and tension from the rope, allows to position the structure at very low cost means at any height above the ground.

By attaching the housing between the center of gravity and the inlet opening, this turns into the flow.

Several constructions can be mounted one above the other. With little effort, the best positions can be achieved which are usually above the ground, which usually causes a flow resistance.

The fulcrums and the generator can be designed as a kind of diving bell by a gas under pressure protect the housing contents from penetrating water. Advantageous with a long thin inlet pipe.

Another variant is that the engine and the housing is integrated in a dam which separates the sea and a basin from each other. The tidal stroke creates a different pressure on the two sides of the wall and corresponding to the engine chambers from the inlet and outlet which sets the engine in motion.

According to the size of the pool, the number of motors can be varied, adjusted.

For environmental purposes, the dam can also be provided with an opening which allows animals each to change the page.

The ratio of the hole size for the animals should be significantly smaller, less than 10% to the sum of the inlet sizes of the engines. Very dense walls are preferable if no environmental conditions are to be met.

The housing may be designed as a tube, each with a parallel to the axis of rotation mounted partition between the likewise drawn in length inlet and outlet ports of two adjacent piston chambers and a rearwardly tapered wall which divides the room again.

This results in an equally executed on both sides hopper on an inlet, respectively an outlet when the flow direction changes. The chambers can also be designed in different design and size, for example, only one side as an open slot and on the other side of the piston chamber as a housing which keeps the pressure difference upright.

The particular advantage of the rotary engine with respect to a turbine is that the piston seals the system and only moves water when the piston is rotated at the same time.

In certain positions, especially with multiple piston corners, a narrow passage can occur.

Brushes, bristles can be attached for sealing between the piston chambers.

The piston can be manufactured as a sheet metal construction or as a tube, compression molding tube which can be cut to the desired length and installed between the mechanics. Also various other types of plastic, carbon fibers and resins wood materials, etc. are conceivable.

As a further variant of the rotary engine can also be used instead of a turbine in a wave power plant, in which by the wave shock compressed air is generated which drives the engine.

For optimum production conditions, the piston plus construction material for the outer casing just fits in a container.

Fig. 1 shows schematically a cross section through a Wankelgeometrie without valve control with a ratio 4/5 from the gear 1 to the inner ring gear 2 with corresponding geometry of a pentagon which rotates in a rounded square and so forms chambers 3 for expansion. If the piston is to rotate in a clockwise direction, then the pressurized medium flows from the opening 4 into the chamber and leaves it again through the opening 5. Sufficiently large feed channels ensure a good supply without excessive pressure drop.

The construction can be made filigree with webs 6 or sheet metal which allow a lightweight rigid construction. Advantageously, the triangular geometry for stiffening and the bow to absorb the pressures which can be connected together in a node 7.

Fig. 2 shows schematically a variant of execution which is also suitable for use in rivers with a tapered vessel 8 in which a pulled in length Wankelmotor 9 is located. Through an opening 10, slots, the water flows radially on the rotary piston. Due to the length of the slots or their number, an adapted outflow rate to the vessel opening 11 can be generated. At the end of the vessel, the water is passed into another tube 12 which is still connected as a slot with the piston chamber. The discharge tube 13 is closed in the front part and in the rear part, after the funnel for a generous outflow reopened, the feed tube just reversed. A motor 14 drives a generator 15 via a shaft 14. A protective grid 16 shown here for a better overview, which is advantageously mounted obliquely in front of or on the opening derives alluvial debris. On a suspension 17, the device can be attached to a support cable.

Fig. 3 shows schematically another variant with drainage device according to the venturi principle 18. The water flowing past is accelerated so we travels with the outflowing water 19 with it. The piston of the piston chamber is also separated by a partition wall 20 in chambers for the inlet 21 and chambers for the drain 22. A float 23 keeps the opening close to the water surface.

Fig. 4 shows schematically how the device when used in a flow with ropes 24 is mounted on a further supporting cable 25 to which various such devices can hang or be attached to a bridge.

Fig. 5 shows schematically a variant with two different profile bars, four identical for the housing 26 and one for the piston 27 and box 28, for example made of sheet metal which can be adjusted in size and attached to the housing 33. A spacer 29 provides for a sufficiently large outlet slot 30 and openings 31 in the funnel 32 resulting from the construction, provide sufficient volume flow on the piston to be moved which can be made at low load without support struts, for example, molded steel tube.

A fine grid, a filter to prevent suspended parts from entering the piston chamber expansion space 34 which can be attached via the inlet openings 31 or at the entrance of the funnel is not shown.

It can also be an entire grid or filter box mounted over the engine.

Also not shown is an opening in the rear region of the funnel through which the filtered floating parts can escape back into the main flow.

Fig. 6 shows schematically a construction in flows with the stable main girder carrier 35, inlet funnel 36 into the engine compartment, a trapping funnel 37 serving the inlet funnels, baffles 38 deflecting the flow or stabilizing the housing to a generator 39 of an electronics box 40 the seabed or other suitable sheltered space, an anchoring post 41, a connecting rope 42 at the front of the structure, and floats 43 which keep the formation in a horizontal position.

Fig. 7 shows schematically a variant as a tidal power plant with a rotary engine with the wall 44 the lower water level 45 and the higher water level 46 and a walkway for installation 47 the motor 48 which forms the connection between the two basins. The inlet ports 49 in this example are designed to be open in length and the outlet ports in the hopper 50 are closed respectively open only to the lower water level basin to maintain the pressure differential. The generator 51 is connected to a shaft, possibly a translation with the engine. A grid construction over the entire engine area is not shown here for a better overview. This can be made very large and protects both the engine and living things from each other.

Fig. 8 shows schematically a section through a four-chamber rotary engine, with a round housing outer wall 52, the rotary piston 53 an inlet chamber 54 of the partition wall 55 to the outlet chamber the inlet slot 56 into the piston chamber and the outlet chamber 57th

Fig. 9 shows schematically a piston which is constructed of sheet metal with truss, with the end face 58 which carries the mechanics as the internal gear with the plate 59 a web 60 for stiffening can be created or cranked, for example, by deep drawing, a main support tube 61, truss rods 62 for stabilization, and transverse struts 63.

Claims (8)

1. hydrofluorine power plant, tidal power plant, characterized in that the water penetrates through an opening 31 in the displacement of a rotary piston motor 3, which is pulled along the axis of rotation in the length and this through another opening 5 again in a separate space from the inlet in which a smaller Pressure prevails. 2. Device for carrying out the method according to claim 1, characterized in that the motor housing a funnel 37, a housing is located, which directs the flow through inlet openings on the piston. 3. Device according to one of the preceding claims, characterized in that the motor has a geometry according to the Wankelmotorenprinzip, with a gear ratio of 1: 2, 2: 3, 3: 4 .... or x: x + 1 from the gear to internal ring gear. 4. Device according to one of the preceding claims, characterized in that no gear or internal gear are used, but the piston rotates based on the housing geometry and judges. 5. Device according to one of the preceding claims, characterized in that the motor dimension for a tidal power plant is at least 50 cm in width and height and at least 60 cm in length and can be up to several meters in size. 6. Device according to one of the preceding claims, characterized in that the density of the piston as accurately as possible but not more than 60% deviates from the density of the ambient water. 7. Device according to one of the preceding claims, characterized in that, in a floating design with buoyancy, the attachment of the tensioning cable between the center of gravity and the inlet opening is, so that the elongated structure by the flow itself in an optimal position with a normal positioned to the flow-oriented inlet opening. 8. Method of making the construction of the designated technology presented in this patent.