NO782823L - BOELGEKRAFTMASKIN. - Google Patents

Description

The invention relates to energy conversion and more specifically to the conversion of energy from the movement of waves in a liquid.

Wave motion has long been regarded as a potential source of power generation, and many proposals have been made for extracting this power, e.g. British patent no.

.......... (British Patent Application No. 30142/76).

According to the present invention, a device is provided which is affected by wave motion, comprising one or more liquid wave-operated pumps, each pump comprising a surface float or foot which partly follows changes in the level of the liquid surface during the passage of waves, a compliant pipe which is suspended in the float, which tube is capable of changing volume when extended or contracted and having unidirectional inlet and outlet valves and a device for maintaining the lower end of the tube at a substantially constant friction level below the surface of the liquid.

In use of the device, the relative movement of the surface float or raft and the lower end of the pipe will cause fluid to be pumped into the pipe through an inlet valve when the pipe volume increases and through an outlet valve when the pipe volume decreases. The resulting water flow can thereby e.g. is fed into a turbine or similar for the provision of electricity.

Where the capacity of one pump is insufficient,

can several pumps be arranged! a setup to pump more liquid. In an arrangement of pumps, it is advantageous to link each pump module with a liquid base body at the surface and a body with a greater density than the surrounding fluid below the surface.

An arrangement of pumps may extend as a line above the surface of the fluid or as a raft in both dimensions above the surface. Where the pump unit is arranged in a line, each pump can be exposed to equal wave conditions. In the case of a two-dimensional surface raft with right angles to the wave front, the pumps closest to the arriving wave will be exposed to full wave action, while those located further away from this edge will be exposed to progressively attenuated waves. An array of pumps may be connected by a system of branch pipes to collect the water pumped from the outlet valves. In the case of normal wind-driven sea waves, the interrupted water flow from each unit in an array of pumps will be added to the branch pipe system to provide a more even flow at the branch pipe outlet.

When the tube is stretched from its normal free length it can exert a restoring force to resume its original length. The wave energy device can also be operated with pipes that exert a retroactive force when they are compressed. The changes in length of the pipe caused by the wave motion represent a change in the enclosed volume of the pipe as in an accordion. Preferably, the change in volume of the compliant tube will cause unidirectional fluid flows by drawing fluid through the one-way inlet valve system, while the volume of the tube increases and pushes fluid out through a second one-way valve system to e.g. a manifold or manifold as the volume decreases.

Additional valves can be used between the inlet valve and the outlet valve if desired, e.g. to minimize backflow. The pipe must have sufficient structural strength to withstand changes in its volume caused by the waves while being exposed to fluctuating pressures associated with pumping the fluid. The pipe can take the form of a flexible channel, e.g. a bellows-shaped vacuum cleaner hose, where the required restoring force during extension and/or compression is provided by a helical spring enclosed by, embedded in or uncoated with a flexible covering, e.g. of softened polyvinyl chloride, synthetic or natural rubbers. The springs can be made of corrosion-resistant material, e.g. stainless steel, or enclosed in a protective pocket in the outer cover.

In an alternative embodiment of the unidirectional valves, a continuous bellows section can have one or more conical protrusions, and preferably the diameter of each conical protrusion tapers in the direction of the advancement of the liquid wave along the device.

In another alternative form, the inner wall of the liquid pipe can be designed so that it provides a low resistance to liquid flow in one direction and a high resistance to the opposite flow. One or more flow regulation sections thus cause unidirectional pumping of liquid. The unidirectional liquid flow can then be used directly for mechanical work or to generate electricity.

In a further alternative embodiment, the flow-regulating part of the liquid pipe is made of an essentially rigid material, while the connecting part is made of a flexible material, whereby the flexibility effects a straightening of the liquid flow along the liquid pipe.

The device is used in shallow water, e.g. where the wavelength of the longest wave in which the device is to operate is greater than twice the water depth, it is advantageous to attach the lower end of the pump pipe to an anchoring system on the seabed to provide a vertical restraint to the buoyancy forces. In deeper water, the anchoring system is preferably a plate of a grid which is suspended from the pump pipe sufficiently far below the surface to be largely unaffected by the surface waves. The plate or grid has a large hydraulic impedance to provide a hold against the surface buoyancy and has sufficient weight to return the plate to its position in calm water against the upward force exerted by the pump tube when operating in waves. When the pumps are connected in an arrangement with a flexible base body at the surface to form a raft, the underwater plates or grids will preferably be connected by a corresponding base body.

The surface base material. and the underwater body material may take the form of nets of natural fibers or plastic ropes or grids or mats of plastic wood or metal.

The underwater plate or grid (reaction plate) is preferably equipped with inflatable chambers that can be filled with air during launching and towing to the place of use•. to reduce draft for the system. A subsequent filling of the chambers allows the underwater plate to sink to the desired operating level.

The structure is equipped with suitable devices for towing and positioning, e.g. cables and ropes, and also for anchoring purposes. The anchoring can be carried out using rope or wire, e.g. nylon ropes or chains to a buoy or directly to anchors on the seabed.

The design of the device is determined by the operating wave conditions and the type of fluid flow required. First, in stages, the underwater plate should have sufficient weight to cause the buoyancy units to be almost half submerged in still water

Preferably, the floats at the surface of the water are designed with a sufficient excess of buoyancy over that necessary to float in still water, so that they can just remain at the surface during the passage of the maximum wave crest expected, while the pump tube is extended by approximately half of the height of the wave. The return force of the tube upon return to the normal contracted length thereby determines the maximum pressure pumped by each unit. For a given set of wave condition geysers, the tubes can be selected to pump a small volume at relatively high pressure or a high volume at low pressure or an intermediate combination.

The device can be used for various water pump operations, e.g. for inflating a wave attenuation bilge or pumping seawater for track element extraction attachments.

The device can be used to pump fluids in which waves occur or by the arrangement of manifolds to both the inlet valves and the outlet valves to pump another liquid or air in a closed circuit.

For seawater operation, the construction materials should be resistant to corrosion and marine fouling.

In the following, the invention will be described in more detail with the help of exemplary embodiments which are shown in the drawings, which show: fig. 1 a vertical section through a wave energy producing device comprising a single vertical compliant tube pump unit,

fig. 2 and 3 plan section and vertical section of a multi-unit device that uses vertical pumps,

fig. 4, 5 and 6 different versions of flexible pipes.

In fig. 1 shows a surface float of foam plastic 1 which supports a bellows tube 2 of a screw-wound steel part which is coated with plastic. The underwater plate 3 is attached to the pipe 2. When a wave crest causes the float to rise, the underwater plate, which is in still water, will counteract the upward movement and cause the bellows to stretch. The resulting increase in volume is accompanied by the flow of water through a coarse filter 4 and a one-way inlet rubber flap valve 5. As the wave crest passes and a wave trough approaches, the restoring force in the extended bellows will cause a contraction and pumping out of water through the outlet valve 6.

Fig. 2 and 3 show an arrangement of several pumps for wave power. An array of pumps can be used together to pump large quantities of seawater to generate electricity. A number of surface floats 1 comprising blocks of foam plastic material are placed on a surface grid 7, and the buoyancy produced is essentially in excess of what is required just to effect a float.

A manifold pipe 8, which is open at one end, is attached to the float 1, and a number of pipes 2 are connected to the manifold pipe 8 and pass vertically to an underwater grid plate 3. The pipes 2 have the shape of an accordion or bellows having a tendency to regain their shape when compressed or elongated.

Each vertical pipe 2 has a one-way valve at one end. The valve at the end of the tube 2 at the underwater grid plate 3 allows only liquid to enter the tube 2, while the valve at the float-. that of pipe 2 only allows liquid to pass from pipe 2 to manifold pipe 8. Valve 5 simply comprises a rubber tab attached to a pivot point at the end of the pipe.

For use in seawater, it is desirable to place a filter 4 at the inlet to the pipes 2 to reduce the possibility of valve blockage.

When using the device, an incoming liquid wave will cause the float 1 to move in step with the wave. Due to its inherent inertia, the underwater grid plate 3 will remain essentially at the same liquid height, and thus a relative movement between the raft 1 and the anchoring plate 3 will cause an alternating compression and extension of the pipe 2 when the incoming wave passes. Thus, when a particular float 1 rises upon the arrival of a wave crest, the associated inlet flap valve 5 will open as the water is drawn through the filter 4 into the pipe 2. When the float 1 falls with an arriving wave due to the restoring force of the extended pipe 2, water is forced out of the outlet valve 6 into the manifold 8. The manifold, which is itself flexible, collects water from all pump units and leads back to the turbine unit 9 which flows in protected water behind the setup away from incoming waves. Turbine 9 then returns water to the sea. The water flow is the result of many pumps that are all driven out of phase and store water in the turbine tube.

The set-up•can be moored from the underwater plate 3 to ordinary anchors or concrete blocks.

Experiments on models for the pumping system were .' carried out in a wave tank with dimensions 16 x 3.6 x 1.2 m. The simple pump unit consisted of one buoyancy cell 1 with dimensions 150 x 205 x 50.mm.. • with a length of 35 mm in diameter of an ordinary vacuum cleaner suction hose 2 suspended vertically below it. This was attached to the buoyancy 1 by means of a T-tube piece with a diameter of 32 mm, as shown in fig. 1. The pipe length was 220 mm (compressed) and 600 mm (freely hanging in the water).

One-way valves 6 made up of stainless steel disks with a diameter of 32 mm and of nylon-reinforced polychloroprene were placed at each end of the pipe 2, so that the direction of flow in the pipe was vertically upwards towards the buoyancy buoy. The characteristics of the pump pipe 2 were varied by changing the anchored level of the lower end of the pipe using an idealized system of a clamp attached to the tank. The results are shown in Table 1. The flow rate for a single pump unit operated in an area of wave conditions was measured for a series of working extensions (pump pipe length when the lower end was attached and the surface float was in still water). This flow rate was determined with the inlet pipe 220 mm above the static water level, i.e. a working pressure of approx. 0.0 2 kg/cm 2 gauge pressure. The results showed that the unit had an optimal working extension between 700 and 730 mm. Above and below this size, the flow rate decreased.

Fig. 4, 5 and 6 illustrate different designs for flexible pipes. Fig. 4 shows a flexible continuous tube with a corrugated shape like a bellows or an accordion. Eminent cones or other suitable shapes are attached to the inner walls of the bellows or accordions. Suitable projecting cones are funnels 10 with the stem part cut off, the circumference of the funnel being attached continuously around the inner 11 to the bellows or accordion for the formation of a series of valves. Fig. 5 shows a modified form of the tube which alter- natively has flexible corrugated sections 12 and rigid sections 13. The rigid sections 13 have . flow regulation units or projections 14. Fig. 6 shows a further form of pipe with internal flow regulation units or projections 15. During movement of the pipe, the positions of the projections 15 will change (as indicated by dashed lines). The contour of the interior of the pipe allows opposite pairs of protrusions to act as one-way valves and effect a unidirectional pumping of water into the pipe.

Claims (15)

1. Device for converting wave energy, characterized in that it comprises one or more liquid-wave-operated pumps, each pump comprising a floating body or a raft on the surface which partially adapts to the changes in the level of the liquid surface during the passage of waves, a compliant tube suspended from the floating body or raft, which tube is capable of changing volume when extended or contracted, and with unidirectional inlet and outlet valves and a device for maintaining the lower end of the tube at a substantially constant level below the surface of the liquid. 2. Device according to claim 1, characterized in that the compliant tube is one flexible channel in which a helical spring is enclosed by or embedded in or coated with a flexible covering. 3. Device according to claim 2, characterized in that the flexible cover is softened polyvinyl chloride, synthetic rubber or natural rubber. 4. Device according to claim 2, characterized in that. the spring is made of a corrosion-resistant metal. 5. Device according to claim 2, characterized in that the spring is enclosed in a protective pocket.. 6. Device according to claim 1, characterized in that the yielding tube is a spring-loaded bellows. 7. Device according to claim 1, characterized in that at least one of the one-way valves is a one-way valve. 8. Device according to claim 1, characterized in that the unidirectional valves comprise a continuous bellows section with one or more conical projections, the diameter of each conical projection tapering in the direction of the flow of the liquid wave along the device. 9. Device according to claim 1, characterized in that the inner wall of the compliant tube has a contour to provide a low resistance to liquid flow in one direction and a high resistance to liquid flow in the opposite direction. 10. Device according to claim 1, characterized in that the compliant pipe comprises rigid pipe sections with conical projections that taper in the direction of the path of the liquid wave connected to compliant pipe parts. 11. Device according to claim 1, characterized in that the retaining device is a plate or a grid with a large hydraulic impedance against vertical movement caused by liquid waves acting on the floating body or the raft on the surface. 12. Device according to claim 11, characterized in that the plate or grid is equipped with inflatable chambers that are able to be filled with air during launching and towing to the place of use, the chamber can then be emptied until the plate or grid sinks to the desired level of use. 13. Device according to claim 1, characterized in that the floating body or raft on the surface comprises a grid or a mat, inherent buoyancy or is attached to the buoyancy body. 14. Device' according to claim 1, characterized in that the grid or the mat is made of wood or plastic material. 15.. Device according to one of the preceding claims, characterized in that the liquid that is pumped is used to drive energy-generating equipment directly or indirectly.