AU2022221375A1

AU2022221375A1 - Solution of maximizing differential motions

Info

Publication number: AU2022221375A1
Application number: AU2022221375A
Authority: AU
Inventors: Thanh Tri Lam
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-08-17
Filing date: 2022-08-22
Publication date: 2022-11-10
Also published as: AU2022218636B2; AU2022221575A1; AU2022218602A1; AU2022218615A1; AU2022218587A1; AU2022218586A1; AU2022221376A1; AU2022218609A1; AU2023282209A1; AU2022218600B2; AU2022218546A1; AU2022218552A1; AU2022218586B2; AU2022218537A1; AU2022218538B2; AU2022218538A1; AU2022218637A1; AU2022218638A1; AU2022218636A1; AU2022256200A1

Abstract

The Solution of Maximizing Differential Motions (SMDM) helps to maximize creating differential motions of rotors and stators from motions of waves for wave energy convertors. It is done with applying: (1) The most efficient damping systems in order to minimize oscillations of stators; and (2) Appropriate mechanisms which are capable to utilize the whole waves from tops to bottoms for harvesting wave energy.

Description

TITLE: SOLUTION OF MAXIMIZING DIFFERENTIAL MOTIONS FIELD

[0001] It is related to the fields of:

(1) Ocean Engineering and Structural Engineering (Structural Mechanics, Structural

Dynamics, Fluid Mechanics (Hydrodynamics).

(2) Wave energy convertors, wind turbines, damping systems, mechanical power

transmission systems.

DESCRIPTION

1.1 The Solution of Maximizing Differential Motions (SMDM) (Figure 1)

[0229] The method helps to maximize creating differential motions of rotors and

stators from motions of waves for wave energy convertors or wave energy systems. It

is applied for wave energy systems, including wave energy convertors with either

linear or rotational electric generators.

[0230] Typical floating wave energy convertor (WEC)s usually use a mechanical

damping device or electronic controlled damping device connecting two component

groups of a floating WEC: The first group is connected to a stator and the second group

is connected to a rotor of an electric generator. This type of damping device might be

called "Internal Damper" because:

(1) it is usually built inside wave energy convertors, and

(2) it connects two component groups of the WEC directly. Thus, each group is

being damped by the mass of the other group via the damper.

[0231] Thus, as a result of damping effects, motions of waves cause oscillations of

these groups differently. This leads to creating differential motions of rotors and

stators for generating electricity. These (internal) damping devices work similar to

springs. However, limits of such a damper possibly are:

(1) As Internal Dampers are usually fit inside floating wave energy convertors, the

travel range of linear motions of the Internal Dampers might be quite limit in

comparison with wave heights like that of offshore waves. This leads to wasting

wave energy.

(2) Life time or mechanical spring might be quite limit for continuous motions of

waves whereas electronic controlled springs might be expensive and require

much maintenance.

(3) Capacities of dampers might be limit in comparison with huge energy of waves

and heavy weights of devices. Thus, these dampers may only cope with a small

portion of wave energy and seem to be appropriate to small waves.

[0232] The developed SMDM does not apply dampers connecting the first and the

second groups (called the Stationed Group and the Movable Group) directly. In other

words, instead of sticking these Groups together via Internal Dampers with limits of

linear motions, the SMDM applies damping externally. Features of the SMDM are

listed below:

(1) A number of External Dampers (#1) (such as an Inertial Hydrodynamic Based

Damper, particularly a SHHD, or the Flexible Porous Net of Wave Absorbers/

Dampers (FPNWA/D), or the Ground) hook to the Floating Posts (#8) or the

Stationed Floats (#3) of the Stationed Group (#3, #8, #9) which includes the

system's floating structure (#3, #8 and #9), via (Vertical) Stationed Ropes/

Cables (#2). The (Vertical) Stationed Ropes/ Cables limits motions, which are

caused by waves, of the Stationed Group, including the Stationed Floats,

Floating Posts and the floating structure of the whole wave energy system.

(2) A compound of (Vertically) Slidable Floats (#4 or#10 or#11) slidable alongthe

Floating Posts (#8) from its bottom sliding limit to top sliding limit positions.

(3) The Floating Post is secured vertically to the floating structure (#3, #8 and #9)

of the system. It should be tall enough for the (Vertically) Slidable Floats to

slide covering from bottoms (#10) to tops (#4) of waves. The distance between

the top sliding limit and the bottom sliding limit positions of the Floating Post

for sliding the (Vertically) Slidable Floats is called Sliding Range.

(4) The floating structure of the whole wave energy systems is set to be stationed

(a part is floating and a part is being submerged) at the surface of water as

explained in descriptions of The Method of Controlled Variable Elevation

(MCVE), and The Method of Automatic Controlled Stationed Rope (MACSR) as

well as the Surrounding Prestressed Floating Post (SPFP).

[0233] As the (Vertically) Slidable Floats are able to slide from bottoms (#10) to tops

(#4) of waves while the Stationed Floats are being hold firmly around its equilibrium

position by appropriate External Dampers, which are possible to provide appropriate

damping efficiencies, the differential motions between the Stationed Floats and the

(Vertically) Slidable Floats are able to be maximized. As a result, the differential motions (called Differential Motions) between the rotors and the stators of generators are also possible to be maximized.

[0234] The key developed features of the SMDM are:

(1) Maximizing Differential Motions by using two floats (Stationed Floats and

(Vertically) Slidable Floats) with External Dampers instead of using one float.

(2) Maximizing Sliding Range of (Vertically) Slidable Floats by:

(a) Maximizing Differential Motions, and

(b) using a Floating Post integrated with sliding rails (such as the Surrounding

Prestressed Floating Post (SPFP) integrated with the (Prestressed)

Structural Rail Tube/ Beam), making the (Vertically) Slidable Floats to be

able to reach tops and bottoms of waves.

(c) As the (Vertically) Slidable Float is developed to be able to slide upwards

and downwards, fully covering from tops to bottoms of waves, the SMDM

can help to harvest more wave energy.

[0235] A wave energy system includes a number of External Dampers, (Vertically)

Slidable Floats, Stationed Floats, Stationed Ropes and Floating Posts which are key

components related to the SMDM.

Claims

1. The Solution of Maximizing Differential Motions (SMDM) comprising:

a number of Floating Posts, including the Surrounding Prestressed Floating Post (SPFP)s;

and

a number of Vertical Sliding Floating Structure (VSFS)s sliding along the Floating Posts or

the SPFPs; and

a number of (Vertically) Slidable Floats secured to the VSFS; and

a number of Stationed Floats secured to the Floating Posts or the SPFPs; and

a number of External Dampers or Damping Systems, including the Submerged Hanging

Hollow Damper (SHHD)s and the Flexible Porous Net of Wave Absorbers/ Dampers

(FPNWA/D); and

a number of Stationed Ropes hanging the External Dampers to the Floating Posts or the

SPFPs; and

a number of Stationed Ropes anchoring the Floating Posts orthe SPFPs to ground; and

the Method of Automatic Controlled Stationed Rope (MACSR); and

the Method of Controlled Variable Elevation (MCVE); and

the arrangement of the above components.