GB2616421A

GB2616421A - A wave energy converter system

Info

Publication number: GB2616421A
Application number: GB2203096.9A
Authority: GB
Inventors: Korez Penley Aslihan
Original assignee: Zoex Ltd
Current assignee: Zoex Ltd
Priority date: 2022-03-07
Filing date: 2022-03-07
Publication date: 2023-09-13
Also published as: WO2023170665A1; GB202203096D0

Abstract

A wave energy converter system (1, figure 1) comprises at least one connection element (2, figure 1) connected to a marine manmade structure (M, figure 1), at least one link structure (3, figure 1) connected to connection element (2, figure 1) via at least two main bearings (4, figure 3), and at least one power take-off module (5, figure 3) to convert linear motion into electricity. The power take-off module comprises at least one primary actuator (6, figure 3), such as a hydraulic piston and cylinder, attached to the link structure, at least one secondary actuator (7, figure 3), such as a hydraulic piston and cylinder, attached to the connection element for tidal tracking, maintenance and survivability modes, at least one rocker 8 attached directly to the secondary actuator and attached to the primary actuator via a link 9, and at least one floating pneumatic fender (10, figure 1) attached to the link structure by a strapping arrangement.

Description

DESCRIPTION

A WAVE ENERGY CONVERTER SYSTEM

Technical Field

This invention relates to a wave energy converter system which is comprised of fender attached to man-made structures by a link structure and converts the wave motion into electricity by generator attached onto said link structure.

Background of the Invention

The world's continuously increasing energy consumption from fossil fuels causes a huge amount of carbon dioxide emissions which contribute to climate change.

This has led researchers and people to search for more sustainable technologies, which does not have the harmful emissions. The renewable energy-based systems such as solar, wind, hydro and biomass is now established however the same success hasn't happened with the vast energy in ocean waves due to high cost.

Wave energy systems need to find a niche market to develop and reduce cost with economies of scale so that they can also join this renewable energy mix. Therefore, we focused our invention on application in several market sectors including breakwaters, marine platforms, maritime, defense, offshore oil and gas, offshore wind, offshore aquaculture and remote coastal communities so that from there with scale of economies, we can drop the cost and join the renewable energy mix. These offshore industries, or another name for it is the "Blue Economy-, uses diesel generators as power and/or auxiliary power which needs to be phased out by 2045 under the UK binding Net Zero Policy. There are not many viable renewable energy alternatives that can replace diesel. These Industries are moving more and more offshore which makes renewable energy from shore (mainland) cable cost prohibitive. There is floating solar, however this does not work in northern latitudes where many of offshore sites are located, there is simply no sun light during winter months. There is small vertical wind solution, however this takes space on the barge/platform and may affect the stability of the barge. Tidal current may or may not be available at the selected site. Therefore, there is an immediate market need for a viable wave energy device to serve these Offshore Industries.

Over the years, many ingenious wave systems have been proposed; some have been built, tested and even demonstrated useful power yet none has so far demonstrated a commercially viable system in operation. For instance, float and buoy systems are used in the state of the art and said float and buoy systems is mounted to the breakwaters. Float and buoy systems in the wave energy systems use the rise and fall of the water body and drive the hydraulic pumps. A series of anchored floats and buoys rise and fall of the wave and said movement is used to run a generator to produce electricity.

In the state of the art, the Chinese patent document no. CN109183712 discloses water tank type floating breakwater for configuring a power generating device, which can effectively absorb and eliminate external wave energy, and can effectively reduce the swing of the breakwater under the impact of waves by the sloshing phenomenon in the water tank. Said water tank type floating breakwater includes a water tank and a plurality of anchor chains are installed outside the water tank, and the water tank is moored to the seabed through the said anchor chain.

In the state of the art, the Chinese patent document no. CN106968871 discloses a multisection floating wave energy electromagnetic generator comprising N electromagnetic power generation sections and a flexible cable respectively. Said multi-section floating type wave energy electromagnetic generator can be used for collecting wave energy in oceans, lakes and rivers, and achieves conversion from wave energy to electric energy along with movement of waves.

In the state of the art, the United States patent document no. US7956478B2 discloses a wave power apparatus comprising a plurality of arms, each of which is rotationally supported at one end by a shaft, and wherein each arm carries a float at its other end, which is opposite to the supported end, so that a translational movement of the float caused by a wave results in rotation of the arm around the shaft, the apparatus comprising power conversion means for converting power transmitted from the wave to the arms into electric power.

In the state of the art, one of the problems in the wave energy system is that a viable wave energy device cannot be provided. The existing wave energy systems do not fulfil the generating power effectively in small waves or surviving the most extreme waves. We can describe this problem as the end-stop problem. A mechanical hard stop (or end stop) will result in high structural loading and the potential for catastrophic failure if it acts to retain the free motion of the device. As it is difficult to predict the maximum wave that a given site will experience during the lifetime of a device end stops should be avoided where possible. Said end-stop problem creates a design trade-off between having a sufficiently large range of motion to accommodate extreme waves whilst having adequate resolution to generate efficiently in small sea states.

Summary of the Invention

An objective of the present invention is to realize a wave energy converter system comprising of fenders attached to man-made structures with a link structure and converts the wave motion into clean-electricity by the generators attached to said link structure.

Another objective of the invention is to realize a wave energy converter system for attaching to man-made marine structures in locations subjected to both wave energy and tidal variation and optimized to extract energy from the smallest waves whilst surviving the most extreme.

Another objective of the present Invention is to realize a modular wave energy converter system wherein the fenders are pivoting with a mechanical intensifier mechanism to move through an operating arc of 180 degrees without encountering a mechanical end-stop, whilst concentrating the full working stroke of the generators to a narrow operating angle of less than 15 degrees.

Another objective of the present invention is to realize a modular wave energy converter system mounted directly onto a range of marine manmade structures such as breakwaters, jetties, barges, platforms, etc. and wherein the modular units are installed in an array for increased generation capacity.

Detailed Description of the Invention

"A Wave Energy Converter System" realized to fulfil the objective of the present invention is shown in the figure attached, in which: Figure 1 is a side view of the inventive converter system on the wave surface (WS).

Figure 2 is a top view of the inventive converter system.

Figure 3 is a top view of the main bearings, primary actuator and secondary actuator.

Figure 4 is a side view of the bearings and links in the PTO module Figure 5 is a side view of the inventive converter system in maintenance status.

Figure 6 is a side view of the inventive converter system in submerged status.

Figure 7 is the lifted up shape of the inventive converter in maintenance and survivability.

The components illustrated in the figures are individually numbered, where the numbers refer to the following: 1. Converter system 2. Connection element 3. Link structure 4. Main bearing 5. PTO (power take off) module 6. Primary actuator 7. Secondary actuator 8. Rocker 9. Link Fender 11 Electrical and Auxiliary Cabinet M: Marine Manmade structure WS: Wave Surface The inventive wave energy converter system (1) for converting wave motion into electricity comprises: -at least one connection element (2) which is connected to marine manmade structures (NI), -at least one link structure (3) which is connected to connection element (2) via at least two main bearing (4), -at least one power take off (PTO) module (5) to convert linear motion to raw electrical output, comprising; at least one primary actuator (6) attached to the link structure (3), at least one secondary actuator (7) attached to the connection element (2) for tidal tracking and maintenance & survivability modes, at least one rocker (8) attached directly to the secondary actuator (7) and, attached to the primary actuator (6) via a link (9) and -at least one pneumatic fender (10) attached to the link structure (3) by a strapping arrangement In the preferred embodiment of the invention, the connection element (2) is the main structural interface element between the link structure (3) and connected marine manmade structure (M). Also, the connection element (2) comprises two hinge points for main bearings (4) for the connection to the link structure (3). In another use of the invention, the connection element (2) comprises a sliding mechanism (not shown on figures) connected to a wall rail. Said sliding mechanism aims to adjust the position of the connection element (3) in relation to the mean waterline level which is affected by the tides. The sliding mechanism comprises four sets of roller assemblies for distribute the hydrodynamic loads from the fender (10) to the wall rails and on the break water structure. The roller assemblies on the sliding mechanism incorporate a breaking mechanism to ensure the position of the carriage at desired level is held in place at the desired vertical position. The sliding mechanism must be locked with said breaking mechanism in place during normal operation and only released periodically to adjust to tidal variation in the mean water level.

In the inventive wave energy converter system (1), the link structure (3) is the main structural element connecting the fender (10) to the main bearings (4). The link structure (3) is rotated with the fender (10) around the main bearing (4) pivot point axis in response to the waves In the preferred embodiment of the invention, the link structure (3) is fabricated from marine grade steel.

In the preferred embodiment of the inventive system PTO module (5) is removable from the link structure (3). In the PTO module (5), the primary actuator (6) is a direct drive linear generator and connected to both rocker (8) via link (9) and link structure (3) The primary actuator (6) converts the rotary motion of the fender (10) to linear motion In the preferred embodiment of the invention, the secondary actuator (7) is a hydraulic cylinder and is used to adjust the maximum power point to track the tidal rise and fall. The PTO module (5) comprises a simple double linkage mechanism for gearing and creates a non-linear relationship between the main bearing (4) pivot angle and stroke of the primary actuator (6). The double linkage mechanism is to convert the working stroke into a small working angle while allowing unrestricted movement through the full range (180 degree) for maintenance and survivability modes.

In the PTO module (5), secondary actuator (7) is attached to connection element (2) from one end via at least one bearing (A). Said secondary actuator (7) is attached from other end to the rocker (8) via at least one bearing (B). The rocker (8) is aligned to main bearings (4) and also attached to link (9) via at least three bearing (C) The said link (9) is attached both the rocker (8) via at least two bearing (D) and the primary actuator (6) via at least four bearing (E). Also link (9) is attached to PTO module (5) via at least two bearings (G). The primary actuator (6) is attached from other end to link structure (3) via at least two bearing (H). (Figure 3) In the preferred embodiment of the invention, the fender (10) is a pneumatic fender and the main element of absorbing the energy from the waves and attached to the link structure (3) via the strapping arrangement comprising at least one chain and at least one strap. Said chains attach to both ends of the fenders (10). Said straps wrap around the fenders (10) and fit back to the link structure (3). The strapping arrangement used on the fenders (10) would be attached to the link structure (3) via a shear pin In the inventive wave energy converter system (1), the fender (10) is ballasted with the sea water until it submerges against the manmade structure (M) in a survivability status. (Figure 6). In the submerged status, the hydrostatic force will be reduced although the fender (10) and the link structure (3) and also the hydrostatic force will still be subject to significant dynamic loads In the submerged position, the fender (10) will make contact with the marine manmade structure (M) In the preferred embodiment of the invention, a buoyancy control module (not shown in the figures) manages the transition from submerged status by floating the fender (10) to bring it back to operational status. In the submerged status of the inventive converter system (1), the primary actuator (6) and secondary actuator (7) is used to damp the response of the fender (10) during the transition.

In the preferred embodiment of the invention, the wave energy converter system (1) also comprises a buoyancy control module (not shown in the figures) used to empty the fender (10). The buoyancy control module is used for recovery of the fender (10) in pinch process. In the recovery (pinch) process the secondary actuator (7) extends, the primary actuator (6) remains locked below the pinch point. The secondary actuator (7) lift the link structure (3) to the vertical position and the fender (10) is lifted in a controlled fashion by the primary actuator (6). (Figure 7) The inventive wave energy converter system (1) also comprises at least one cabinet (11) for electrical power conditioning systems. Said cabinet (11) is also used for buoyancy control and secondary power packs.

The inventive wave energy convertor system (1) provides sufficient power to weight ratio to justify the considerable cost of installation, transportation and 20 deployment The inventive energy converter system (1) provides a solution to the problem of efficiently capturing the kinetic energy in small sea-states by using an innovative mechanical intensifier mechanism design that allows the pivoting fender (10) to move through an operating arch of 180 degrees without encountering a mechanical end-stop, whilst concentrating the full working stroke of the primary generator (6) to a narrow operating angle of less than 15 degrees. This simple, yet innovative design offers tangible improvements to the performance of a wave energy converter, particularly in the following areas: * improved survivability-the design eliminated end stop issues providing a more robust long tern solution without requiring active force control to limit motion during extreme wave events.

* improved capacity factor-the intensifier increases the working velocity of the primary generator (6) during small sea-states and progressively detunes once the working angle exceeds the design limit. This allows the system (1) to achieve rated power in significantly smaller sea-states than normally possible due to the practical limitations on the amount of reactive load that can be controllably delivered in a system responding with low relative displacement and velocity. Achieving rated power in small sea-states is key to improving the capacity factor and delivering a reduced overall cost of energy.

* improved use of primary generator (6) capital expenditure -In many WEC designs, the working stroke (and in some cases the PTO design load) is determined by the survival condition rather than the most commonly occurring operational seastate. This leads to an inefficient use of CAPEX with the primary generator (6) capacity rarely utilised effectively. By contrast the mechanical intensifier design allows the full capacity of the converter system (1) to be utilised even in small sea-states Additionally, the present invention provides cuts down the cost by having a connection element (2) that is attachable to any marine manmade structure (N4), in a way converting them into a clean energy device. Partially this is also achieved by using a fender (10) as a wave absorber body instead of a metal float, as the fender (10) does not damage the host structure. On the contrary the fender (10) protects the host structure against impact damage and enhances the pitch and roll stability of floating structures thus increasing personnel safety.

It is possible to develop various embodiments of the inventive wave energy converter system (I); the invention cannot be limited to examples disclosed herein and it is essentially according to claims.

Claims

CLAIMS1. A wave energy converter system (1) for converting wave motion into electricity comprising; -at least one connection element (2) which is connected to marine manmade structures (M), -at least one link structure (3) which is connected to connection element (2) via at least two main bearing (4) and characterized by; -at least one power take off (PTO) module (5) to convert linear motion to raw electrical output, comprising; at least one primary actuator (6) attached to the link structure (3), at least one secondary actuator (7) attached to the connection element (2) for tidal tracking, maintenance and survivability modes at least one rocker (8) attached directly to the secondary actuator (7) and, attached to the primary actuator (6) via a link (9) and -at least one pneumatic fender (10) attached to the link structure (3) by a strapping arrangement.
2. A wave energy converter system (1) according to Claim 1; characterized by the connection element (2) which is the main structural interface element between the link structure (3) and connected directly the marine manmade structures (M).
3 A wave energy converter system (1) according to Claim 1 or 2; characterized by the connection element (2) which comprises two hinge points for main bearings (4) for the connection to the link structure (3).
4 A wave energy converter system (1) according to any of the preceding claims; characterized by the connection element (2) which comprise a sliding mechanism connected to a wall rail.
5. A wave energy converter system (1) according to Claim 4; characterized by said sliding mechanism which aims to adjust the position of the connection element (3) in relation to the mean waterline level which is affected by the tides.
6. A wave energy converter system (1) according to Claim 4 or 5; characterized by the sliding mechanism which comprises four sets of roller assemblies for distribute the hydrodynamic loads from the fender (10) to the wall rails and on the man made structure.
7. A wave energy converter system (1) according to Claim 6; characterized by the roller assemblies on the sliding mechanism incorporates a breaking mechanism to ensure the position of the carriage at desired is held in place at the desired vertical position.
8. A wave energy converter system (1) according to any of the preceding claims; characterized by the link structure (3) which is rotated with the fender (10) around the main bearing (4) pivot point axis in response to the waves.
9. A wave energy converter system (1) according to any of the preceding claims, characterized by the link structure (3) which is fabricated from marine grade steel.
A wave energy converter system (1) according to any of the preceding claims, characterized by the PTO module (5) which is removable to link structure (3).
11. A wave energy converter system (1) according to any of the preceding claims; characterized by the primary actuator (6) which is a direct drive linear generator and is connected both rocker (8) via link (9) and link structure (3).
12. A wave energy converter system (1) according to any of the preceding claims; characterized by the primary actuator (6) which converts the rotary motion of the fender (10) to linear motion.
13. A wave energy converter system (1) according to any of the preceding claims; characterized by the secondary actuator (7) which is a hydraulic cylinder and is used to adjust the maximum power point to track the tidal rise and fall and for maintenance and survival modes.
14. A wave energy converter system (1) according to any of the preceding claims; characterized by the PTO module (5) which comprises a simple double linkage mechanism for gearing and creates a non-linear relationship between the main bearing (4) pivot angle and stroke of the primary actuator (6).
15. A wave energy converter system (1) according to any of the preceding claims; characterized by the fender (10) which is pneumatic fender and the main element absorbing the energy from the waves and attached to the link structure (3) via the strapping arrangement comprising at least one chain and at least one strap.
16. A wave energy converter system (I) according to claim 15; characterized by the chains which attach to both ends of the fender (10).
17 A wave energy converter system (1) according to claim 15 or 16; characterized by the straps which wrap around the fender (10) and fit back to the link structure (3).
18. A wave energy converter system (1) according to any of the preceding claims; characterized by the fender (10) which is ballasted with the sea water until it submerges against the marine man made structure in a survivability status.
19. A wave energy converter system (1) according to any of the preceding claims; comprising a buoyancy control module used to empty the fender (10) bringing it back to the operational mode.
20. A wave energy converter system (1) according to claim 19; characterized by the buoyancy control module which manages the transition from submerged status by floating the fender (10) 21 A wave energy converter system (1) according to any of the preceding claims; comprising at least one cabinet (11) for electrical power conditioning systems.