WO2018125318A2 - Dispositif houlomoteur à inertie - Google Patents

Dispositif houlomoteur à inertie Download PDF

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Publication number
WO2018125318A2
WO2018125318A2 PCT/US2017/051000 US2017051000W WO2018125318A2 WO 2018125318 A2 WO2018125318 A2 WO 2018125318A2 US 2017051000 W US2017051000 W US 2017051000W WO 2018125318 A2 WO2018125318 A2 WO 2018125318A2
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WO
WIPO (PCT)
Prior art keywords
wave energy
energy converter
inertial
pulley
mass
Prior art date
Application number
PCT/US2017/051000
Other languages
English (en)
Other versions
WO2018125318A3 (fr
WO2018125318A9 (fr
Inventor
Brian Lee Moffat
Garth Alexander SHELDON-COULSON
Daniel William PLACE
Rabeh Bassam SHALHOUB
Original Assignee
Brian Lee Moffat
Sheldon Coulson Garth Alexander
Place Daniel William
Shalhoub Rabeh Bassam
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Brian Lee Moffat, Sheldon Coulson Garth Alexander, Place Daniel William, Shalhoub Rabeh Bassam filed Critical Brian Lee Moffat
Priority to NZ752276A priority Critical patent/NZ752276A/en
Priority to AU2017385006A priority patent/AU2017385006B2/en
Publication of WO2018125318A2 publication Critical patent/WO2018125318A2/fr
Publication of WO2018125318A9 publication Critical patent/WO2018125318A9/fr
Priority to ZA2019/02186A priority patent/ZA201902186B/en
Publication of WO2018125318A3 publication Critical patent/WO2018125318A3/fr

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Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F03MACHINES OR ENGINES FOR LIQUIDS; WIND, SPRING, OR WEIGHT MOTORS; PRODUCING MECHANICAL POWER OR A REACTIVE PROPULSIVE THRUST, NOT OTHERWISE PROVIDED FOR
    • F03BMACHINES OR ENGINES FOR LIQUIDS
    • F03B13/00Adaptations of machines or engines for special use; Combinations of machines or engines with driving or driven apparatus; Power stations or aggregates
    • F03B13/12Adaptations of machines or engines for special use; Combinations of machines or engines with driving or driven apparatus; Power stations or aggregates characterised by using wave or tide energy
    • F03B13/14Adaptations of machines or engines for special use; Combinations of machines or engines with driving or driven apparatus; Power stations or aggregates characterised by using wave or tide energy using wave energy
    • F03B13/16Adaptations of machines or engines for special use; Combinations of machines or engines with driving or driven apparatus; Power stations or aggregates characterised by using wave or tide energy using wave energy using the relative movement between a wave-operated member, i.e. a "wom" and another member, i.e. a reaction member or "rem"
    • F03B13/20Adaptations of machines or engines for special use; Combinations of machines or engines with driving or driven apparatus; Power stations or aggregates characterised by using wave or tide energy using wave energy using the relative movement between a wave-operated member, i.e. a "wom" and another member, i.e. a reaction member or "rem" wherein both members, i.e. wom and rem are movable relative to the sea bed or shore
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F03MACHINES OR ENGINES FOR LIQUIDS; WIND, SPRING, OR WEIGHT MOTORS; PRODUCING MECHANICAL POWER OR A REACTIVE PROPULSIVE THRUST, NOT OTHERWISE PROVIDED FOR
    • F03BMACHINES OR ENGINES FOR LIQUIDS
    • F03B13/00Adaptations of machines or engines for special use; Combinations of machines or engines with driving or driven apparatus; Power stations or aggregates
    • F03B13/12Adaptations of machines or engines for special use; Combinations of machines or engines with driving or driven apparatus; Power stations or aggregates characterised by using wave or tide energy
    • F03B13/14Adaptations of machines or engines for special use; Combinations of machines or engines with driving or driven apparatus; Power stations or aggregates characterised by using wave or tide energy using wave energy
    • F03B13/16Adaptations of machines or engines for special use; Combinations of machines or engines with driving or driven apparatus; Power stations or aggregates characterised by using wave or tide energy using wave energy using the relative movement between a wave-operated member, i.e. a "wom" and another member, i.e. a reaction member or "rem"
    • F03B13/18Adaptations of machines or engines for special use; Combinations of machines or engines with driving or driven apparatus; Power stations or aggregates characterised by using wave or tide energy using wave energy using the relative movement between a wave-operated member, i.e. a "wom" and another member, i.e. a reaction member or "rem" where the other member, i.e. rem is fixed, at least at one point, with respect to the sea bed or shore
    • F03B13/1885Adaptations of machines or engines for special use; Combinations of machines or engines with driving or driven apparatus; Power stations or aggregates characterised by using wave or tide energy using wave energy using the relative movement between a wave-operated member, i.e. a "wom" and another member, i.e. a reaction member or "rem" where the other member, i.e. rem is fixed, at least at one point, with respect to the sea bed or shore and the wom is tied to the rem
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F05INDEXING SCHEMES RELATING TO ENGINES OR PUMPS IN VARIOUS SUBCLASSES OF CLASSES F01-F04
    • F05BINDEXING SCHEME RELATING TO WIND, SPRING, WEIGHT, INERTIA OR LIKE MOTORS, TO MACHINES OR ENGINES FOR LIQUIDS COVERED BY SUBCLASSES F03B, F03D AND F03G
    • F05B2260/00Function
    • F05B2260/40Transmission of power
    • F05B2260/406Transmission of power through hydraulic systems
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F05INDEXING SCHEMES RELATING TO ENGINES OR PUMPS IN VARIOUS SUBCLASSES OF CLASSES F01-F04
    • F05BINDEXING SCHEME RELATING TO WIND, SPRING, WEIGHT, INERTIA OR LIKE MOTORS, TO MACHINES OR ENGINES FOR LIQUIDS COVERED BY SUBCLASSES F03B, F03D AND F03G
    • F05B2260/00Function
    • F05B2260/50Kinematic linkage, i.e. transmission of position
    • F05B2260/504Kinematic linkage, i.e. transmission of position using flat or V-belts and pulleys
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E10/00Energy generation through renewable energy sources
    • Y02E10/30Energy from the sea, e.g. using wave energy or salinity gradient

Definitions

  • the amounts of energy that can be extracted from devices of the prior art are meager compared with the expense of fabricating, operating, and maintaining these devices.
  • the scale of the effort, in terms of numbers and sizes of devices will need to be dramatically increased.
  • the prior art lacks an effective manner or technology with which to accomplish this goal.
  • the present invention overcomes the shortcomings of the prior art and
  • converter designed to cost- effectively achieve a high energy conversion efficiency. Moreover, the converter of the present invention exhibits a range of features designed to ensure survival during storms, the longevity of mechanical components, and a low cost of manufacture.
  • the converter of the present disclosure will be characterized by a minimal environmental impact, as well as an ability to optimize system behavior and performance with respect to changing wave conditions.
  • the disclosed converter can be described as being of a “single-mode” and “heave- mode” design. Power is developed and made available for extraction when wave-induced changes in the surface water level (i.e., wave "heave”) contribute to the buoyant vertical acceleration of the flotation module, e.g., driving it upward and away from the submerged and less-easily accelerated inertial mass.
  • the motion differential between the two bodies can enable a power-take-off system (e.g., an electrical power-take-off system, mechanical- electrical power-take-off system, or an hydraulic-electrical power-take-off system) to be actuated and power (e.g., electrical power) to be generated.
  • a power-take-off system e.g., an electrical power-take-off system, mechanical- electrical power-take-off system, or an hydraulic-electrical power-take-off system
  • power e.g., electrical power
  • the flotation module rises and falls on passing waves, and the separation distance between the flotation module and the inertial mass periodically increases and decreases.
  • the separation distance increases, the portion of the flexible connector that is attached to the inertial mass experiences a downward movement relative to the flotation module, or, what is the same thing, the flotation module experiences an upward movement relative to the portion of the flexible connector that is attached to the inertial mass.
  • the converter generates power by opposing this relative movement of the flexible connector using the at least one power- take-off system mounted at or upon the flotation module.
  • the separation distance between the flotation module and inertial mass increases— and the the pulley/capstan is turned because of this increasing separation distance and power is generated (or stored in a mechanical or hydraulic accumulator)— both during periods when the inertial mass is falling and periods when the inertial mass is rising.
  • falling and rising we mean, for clarity, falling and rising relative to the surface of the earth and, if applicable, relative to the still water that surrounds the inertial mass below a wave base.
  • the reason that power can be generated when the inertial mass is falling (in addition to when it is rising) is that the inertial mass's ability to increase a tension in the flexible connector and oppose a separation between the flotation module and inertial mass is related predominantly to the inertial mass's inertia and momentum, not a drag force.
  • the inertial mass would need to be moving upwardly relative to the surrounding water to experience a downward drag force and transmit said drag force to the flexible connector, the inertial mass need not be moving upwardly to transit a downward force to the flexible connector on account of the inertial mass's momentum. Indeed, a great part of the device's power is typically generated while the inertial mass has a downward momentum (relative to the surface of the earth).
  • a periodic peak tension in the flexible connector occurs when the inertial mass is descending (relative to the surface of the earth). In some embodiments, a periodic peak tension in the flexible connector occurs when the inertial mass is approximately vertically unmoving (relative to the surface of the earth). In any case, a tension in the flexible connector is not necessarily linked to a downward drag force acting on the inertial mass, and a maximal tension in the flexible connector is not necessarily coincident with (and in most embodiments is in fact not coincident with) a maximal drag force acting on the inertial mass, nor with a maximal upward velocity of the inertial mass.
  • the inertial mass is “juggled,” or dynamically suspended and oscillated, in at least one operational separation distance range owing to the aforementioned periodic cycle of upward lifting and downward gravitationally-induced falling.
  • operational separation distance range we mean the range defined by the minimum and maximum separation distances attained between the flotation module and inertial mass during a defined period of operation.
  • the dynamic suspension of the inertial mass in an operational separation distance range is accomplished through the periodic conversion of kinetic energy from passing waves into kinetic energy and gravitational potential energy imparted to the inertial mass, mediated by the power-take-off system.
  • the inertial mass would, in some embodiments, tend to fall downward under gravity, and achieve a separation distance outside, and greater than, the aforementioned operational separation distance range; at least unless arrested by a brake or some other mechanism to the same effect, and/or until caught by a tether, and/or until it reaches a parked depth or parked separation distance.
  • some embodiments of the converter preferably operate "out of equilibrium"; the operational separation distance range preferably does not include, and can be significantly spaced from, a resting, or parked, separation distance.
  • a separation distance between the inertial mass and flotation module increases about half the time, and decreases about half the time.
  • separation distance we mean the separation distance between the flotation module and the inertial mass that would come to pass in the event that no waves were present and the power-take-off system were configured to impart no countertorque to the pulley/capstan, so that the inertial mass assumed a position of static equilibrium. And similarly for the resting, or parked, depth of the inertial mass.
  • the inertial mass can be "lifted” or “bootstrapped” to an operational depth range through the application of a countertorque by the power- take-off system in the presence of waves.
  • the larger bound of the operational separation distance range i.e. the deeper bound in the body of water
  • the deeper bound of the operational depth range should be spaced from the inertial mass's resting, or parked, separation distance, by a distance of at least the significant wave height in typical operational conditions.
  • the inertial mass is controlled so as to cause it to oscillate within an operational separation distance range (or, an operational depth range) spaced from a resting, or parked, separation distance (or, spaced from a resting, or parked, depth) by a distance of at least 1.5 times the significant wave height. In some embodiments, the inertial mass is controlled so as to cause it to oscillate within an operational separation distance range (or, an operational depth range) spaced from resting, or parked, separation distance (or, spaced from the resting, or parked, depth) by a distance of at least 5 meters.
  • the depth of the inertial mass, and its separation distance from the flotation module can be regulated by a countertorque control system that can respond adaptively to the vertical position (i.e., depth in the body of water, and/or separation distance from the flotation module) of the inertial mass, and/or to other operational statistics of the converter.
  • a control system can use, apply, and/or create variations in the (instantaneous and/or averaged over a period of time) countertorque applied, and/or resistance to separation applied, by the power-take-off assembly. This can help keep the converter within an optimal range of operating parameters, e.g., keep the inertial mass within a desired depth range and/or a desired separation distance range.
  • the control system can incorporate feedback control with respect to operating parameters such as the depth of the inertial mass and/or the separation distance between the inertial mass and the flotation module.
  • a countertorque control system integrated into the converter can control the generator (and/or a clutch and/or hydraulic valve situated in a force-transmission pathway to the generator) to provide different levels of countertorque to the rotating shaft (and/or to a rotating pulley/capstan) at different times.
  • Such differences in countertorque or resistance can be a function of operational parameters such as the current and/or recent depth of the inertial mass in the body of water, and/or the current and/or recent distance between the inertial mass and the flotation module.
  • differences in countertorque or resistance can be created and/or provided and/or effectuated by varying the excitation of field coils in a generator; by power electronics and control circuits that reduce the load experienced by the generator or that otherwise modulate the generator's behavior (e.g., back-to-back AC/DC converters, and/or a machine-side converter, a grid-side converter and control circuits); by varying the engagement of an electromagnetic or mechanical or hydraulic clutch or valve assembly; or by other means.
  • a mechanical brake is provided so that a stopping force, countertorque, or resistance can be applied to the shaft or pulley from which the inertial mass is suspended in addition to any application of a countertorque by the generator itself.
  • the countertorque control system controls a power-take-off system to decrease the average countertorque applied by the power-take-off system to a
  • the countertorque control system controls a power-take-off system to increase the average countertorque applied by the power-take-off system to a pulley/capstan.
  • Input signals used by the control system can include direct measurements of the approximate depth of the inertial mass, e.g., as measured by downward-pointed sonar mounted on the flotation module, and/or indirect or proxy measurements of the same, e.g., as derived from measurements of the translation of the flexible connector and/or measurements of the angular position of a pulley or rotating capstan.
  • direct measurements of the approximate depth of the inertial mass e.g., as measured by downward-pointed sonar mounted on the flotation module
  • indirect or proxy measurements of the same e.g., as derived from measurements of the translation of the flexible connector and/or measurements of the angular position of a pulley or rotating capstan.
  • one or more rotary encoders measure the angular position of a
  • Some embodiments of the disclosed converter dynamically regulate the vertical position (e.g., depth in the body of water, or separation distance from the flotation module) of the inertial mass in a manner that can depend at least in part on a calculated statistic of the wave energy available in the occurrent sea state.
  • Such a control system can enable the vertical position of the inertial mass to be regulated in a manner that changes depending on wave conditions.
  • Input signals used by such a control system can include signals or statistics relating to the occurrent available wave energy, e.g., the measured or forecast wave height, the measured or forecast wave period, the measured or forecast wind speed, and/or the measured vertical acceleration of the flotation module.
  • Such information can be received by satellite communication and/or by a data network that includes multiple nearby converters.
  • the inertial mass is controlled so as to cause it to oscillate within a first operational separation distance range and then controlled to move (rise or descend) to a second operational separation distance range and then controlled to oscillate in this second operational separation distance range, where the first operational separation distance range is spaced from (e.g. is nonoverlapping) the second operational separation distance range.
  • the inertial mass can be moved to a more advantageous vertical location in the water column (e.g., to avoid currents, or to increase or decrease exposure to residual wave action at different depths, etc.).
  • this controlled ascent and descent can take place only by varying the average countertorque applied by the power-take-off system during dynamic suspension, and not by the use any auxiliary winches or other artifices.
  • the buoyant flotation module is preferably horizontally broad, enabling it to experience a relatively large change in displacement, and hence a relatively large change in buoyant force, for a given change in the surface water level. This enables it to "track" the surface water level relatively closely and thus efficiently convert available wave energy to usable power.
  • the buoyant flotation module is substantially “flat,” like a pancake.
  • the buoyant flotation module has a curved bottom surface that approximately, and at least partially, defines an arc of a circle with respect to at least one vertical cross section, enabling the flotation module to freely rotate in the water (as if borne on a bearing), within the plane of the vertical cross-section in which the buoyant flotation module has a curved bottom surface, to correct misalignments in the fleet angle(s) of the converter's flexible connector(s) (discussed in greater detail below).
  • the flotation module has a bottom surface that at least approximately and at least partially defines a spherical cap or spherical dome.
  • the flotation module has a bottom surface that at least approximately and at least partially defines a horizontal cylindrical segment.
  • at least one pulley/capstan is located in a recessed bottom portion of the flotation module.
  • a top surface of the flotation module has docking interfaces for functional modules that might contain arbitrary electrical equipment. These interfaces can include a power connection, a data connection, and a structural connection, the data connection optionally providing a documented application programming interface for controlling and/or receiving operational statistics of the converter.
  • the structural connection includes Twistlock connections suitable for securing a standard shipping container.
  • a substantial portion of the flotation module is constructed from concrete. Concrete has the advantages of being low-cost, strong, and impervious to corrosion.
  • an outer (circumferential) and/or bottom “shell" of the flotation module is predominantly constructed from concrete, while a top deck of the flotation module is constructed from another material, such as metal.
  • a part of the flotation module is made of successively deposited layers of concrete, such as are deposited by "3D printing” or “additive manufacturing” of concrete.
  • a flotation module composed largely of concrete is structurally strengthened through the use of tensile members configured to "pre-stress" and/or "post- tension” the concrete, predominantly by applying a pre-stressing force in one or more radial/diametrical and/or horizontal directions.
  • pre-stressing is provided by tensile members wrapped and tensioned circumferentially around a perimeter of the flotation module, typically in a plane that is predominantly horizontal, which, when tensioned, compress the structure inward.
  • pre-stressing is provided by tensile members that extend in approximately straight lines through approximately horizontal channels provided in the flotation module, typically transiting a
  • the inertial mass preferably has relatively low drag when moved in the vertical direction.
  • a spherical or elliptical inertial mass i.e. an inertial mass having a spherical or elliptical "shell” enclosing one or more interior volumes of water, e.g. seawater
  • the inertial mass is preferably suspended in a net or other means of coupling it to the flexible connector that supports its bottom portion.
  • the inertial mass is approximately spherical, elliptical, toroidal, or cubical.
  • the inertial mass may be a solid possessing an appropriate and/or suitable density, e.g. concrete containing air-filled voids.
  • the magnitude of the drag force experienced by the inertial mass is a small fraction, ideally a negligible fraction, of the tension in the flexible connector between the inertial mass and flotation module.
  • drag adds a minor contribution to the overall resistance provided by the inertial mass.
  • the overall resistance provided by the inertial mass is primarily a function of its inertia, rather than its drag, magnitude of the resistance it offers (and hence the tension in the flexible connector that it generates) is temporally concentrated during periods when the inertial mass has greatest acceleration, not greatest velocity.
  • the statements above can refer to averages over the course of a wave period, over the course of several wave periods, or over an extended period of operation.
  • a time-averaged absolute value of the drag force acting on the inertial mass over a given period of time can be compared to a time-averaged absolute value of the tension in the flexible connector over the same period of time, and the latter is far greater than the former (e.g. at least 10 times greater in some embodiments, at least 50 times greater in some embodiments, and at least 100 times greater in some embodiments).
  • a peak drag force over the course of given period of time can be compared to a peak tension in the flexible connector over the same period of time, and the latter is far greater than the former (e.g.
  • a periodic local maximum of the drag force acting on the inertial mass occurs at least one fourth of a period, or one fifth of a period, out of phase from a periodic local maximum of a tension in the flexible connector.
  • Included water becomes for all intents and purposes an integral part of the inertial mass and contributes its mass, inertia, and momentum to that of the inertial mass, especially insofar as the inertial mass is given a form and/or features which constrain said water with respect to vertical movement.
  • hydrodynamic added mass can also contribute significantly to the inertia of the inertial mass, it is advantageous if the quotient of (i) the hydrodynamic added mass of the inertial mass to (ii) the mass of "included water" is less than unity, and this is the case in most embodiments of the present disclosure.
  • the ratio of the hydrodynamic added mass of the inertial mass to the mass of included water is typically about one half.
  • inertial mass has a streamlined profile when moving in at least one vertical direction, e.g. it has a curved top and/or bottom profile.
  • this curved profile is "unimodal" i.e. having a single leading portion suitable for parting the water through which it moves when it moves in a vertical direction.
  • all vertical cross sections through the inertial mass show a unimodal curved profile, i.e. a profile with a single leading portion.
  • a spheroid and ellipsoid have a unimodal curved profile in all vertical cross sections, whereas a toroid (oriented so that its hole allows vertical passage) does not.
  • a volume of the enclosed water of the inertial mass is greater than the volumetric displacement of the flotation module.
  • the inertial mass can be constructed inexpensively as a submerged, substantially hollow vessel, container, or enclosure having rigid and/or flexible walls.
  • the hollow interior of the inertial mass can contain seawater that floods an interior of the inertial mass, e.g. upon the converter's initial deployment into a body of water.
  • the inertial mass has concrete walls.
  • the inertial mass has concrete walls composed of multiple successively deposited layers of concrete, such as might be formed by additive manufacturing, i.e. through the "3-D printing" of said concrete.
  • the inertial mass is made of plastic.
  • the inertial mass is made by roto-molding.
  • the inertial mass's walls are defined by flexible cables, sheeting, and/or fabric so that the inertial mass is compact during manufacture, transportation, and deployment yet voluminous once deployed.
  • a top portion of the inertial mass is open, so that the inertial mass takes the shape of a cup or ice cream cone.
  • the inertial mass is a vertically spaced stack of horizontal plates.
  • the inertial mass must have an effective negative buoyancy during operation.
  • effective negative buoyancy we mean that the inertial mass has an average density selected so that when submerged and filled or flooded with water (if applicable), and when at an operational depth range, it will tend to fall and/or be pulled downward under gravity, unless lifted upward by a force applied to it through the at least one flexible connector by which it is connected to the flotation module.
  • the inertial mass's effective negative buoyancy results from its own intrinsic net weight (gravitational weight net of buoyant force) being positive.
  • negative buoyancy is achieved by the combined net weight of the inertial mass and any weighted objects depending from it, and/or enclosed within it, being positive.
  • the inertial mass must have an effective negative buoyancy during operation, some embodiments use a positively or neutrally buoyant inertial mass from which depend one or more weights, chains, or other similar weighted objects that act to give the inertial mass an effective negative buoyancy during operation.
  • the inertial mass does not need to rest upon, be attached to, nor otherwise have direct contact with the seafloor.
  • embodiments of the converter are deployed economically in deep offshore waters (e.g.. depths of over 200 meters), where the ocean wave energy resource is at its greatest but attachment of a converter to the seafloor is economically or practically prohibitive.
  • the depth at which the inertial mass is suspended is at least 50% of the depth of a wave base of the body of water, allowing the inertial mass to experience a relatively small degree of wave-induced water movement in its immediate vicinity.
  • a prevailing wavelength of waves in the body of water is 300 meters
  • a prevailing wave base can be 150 meters
  • the inertial mass is preferably suspended at a depth of at least 75 meters. It is more preferable still for the inertial mass to be suspended near or below a wave base of the body of water.
  • the inertial mass is suspended at a depth of 100 meters, 150 meters, and 200 meters. The inertial mass changes depth during operation.
  • the inertial mass is biased to a greater depth than its operational depth range, and is dynamically suspended in at least one operational depth range by inputs of energy from passing waves.
  • the operational depth range can change through time.
  • the control system of the lifting module can cause the average depth of the inertial mass to increase and decrease.
  • the average depth of the inertial mass can be regulated and stabilized even in radically different wave conditions.
  • the mass of the seawater confined by the inertial mass can be substantial, e.g., many millions of kilograms.
  • This mass of seawater is substantially "trapped" by, within, and/or against the inertial mass (e.g., by, within, and/or against its substantially
  • the inertial mass when the inertial mass is accelerated in a relevant direction.
  • a large mass of water must also move and/or be accelerated in that same direction.
  • the inertial mass's effective mass is very great when used as a foothold, reaction point, or grapple for the flotation module to "pull against” during the latter' s buoyancy-induced ascent.
  • the inertial mass falls under gravity owing to its effective negative buoyancy during operation, a large mass of water is accelerated downward and the momentum of this water contributes to the development of power when the upward lifting force imparted by the flotation module subsequently accelerates the inertial mass in the opposite direction.
  • a cable- and-pulley system is the mechanism by which buoyant work acting upon the flotation module (but resisted by the inertial mass) is converted to mechanical shaft power. At least one cable with one portion bound at the inertial mass applies a torque to a pulley and/or rotating capstan borne at the flotation module, which in turn directly or indirectly operates a generator (or performs some other useful work).
  • the use of a cable- and-pulley system as part of a power-take-off scheme enables a direct conversion of the force of waves into rotary motion suitable to rotate a shaft.
  • multiple pulleys/capstans are mounted at the flotation module.
  • the pulleys/capstans are disposed circumferentially at a perimeter of the flotation module.
  • the pulleys/capstans are disposed at a submerged bottom portion of the flotation module.
  • the pulleys/capstans are disposed at a top central portion of the flotation module, so that the flexible connector passes through one or more apertures in the flotation module.
  • the pulleys/capstans are mechanically linked so that they must rotate at approximately the same rate. In some embodiments, this helps achieve the directional rectification of the flotation module, or in other words to ensure that when the flexible connector is under tension, the bottom of the flotation module points approximately in the direction of the inertial mass (i.e. the flotation module's vertical axis is approximately collinear with a line passing through the flotation module and the inertial mass).
  • the ratio of the pulley diameter to the cable diameter is 40 or greater.
  • the D/d ratio is 50 or greater.
  • the D/d ratio is 50 or greater, or even 60 or greater, or 70 or greater.
  • several design features have had to be invented and/or combined in novel ways in our preferred embodiments, including but not limited to the "ribbon-like" flexible connector described below (i.e. multiple "strands" of a flexible connector winding onto the same pulley drum), and particular locations chosen for placement of pulley drums.
  • the cable diameter refers to the diameter of any one of the constituent cables, and/or to the smallest cross-sectional dimension of the ribbon-like flexible connector, which are typically the same value.
  • a tension in the flexible connector is translated into a torque in the pulley/capstan through the use of traction and/or the capstan effect.
  • the cable is not directly attached to the pulley, but rather transmits a torque through it by binding against it. Friction is required.
  • at least one pulley/capstan is part of a traction winch assembly.
  • at least one pulley/capstan has a flexible connector multiply wound around it in a spiral configuration.
  • a tension in the flexible connector is translated into a torque in the pulley/capstan through a direct attachment of part of (e.g. the end of) the flexible connector to a part of the pulley/capstan, particularly a circumferential part. Accordingly, no friction or traction is required.
  • the amount of available travel is typically more limited than in embodiments where force is transmitted by friction, since once the flexible connector fully “unwinds" from the pulley/capstan, no further rotation of the
  • a rotary member (a pulley/capstan) as the interface structure for the flexible connector it enables the "travel" or "stroke distance” between the inertial mass and the flotation module to be large relative to converters of the prior art.
  • a wave energy converter can experience waves of 15, 20, 25, or even 30 meters in wave height. It is imperative that when the flotation module of a wave energy converter rises 30 meters on a storm wave, it does not encounter any mechanical "hard stops” imposed by the mechanical design of the converter, i.e. sudden limits to further separation of the inertial mass and flotation module. This would quickly contribute to the destruction of the device.
  • a flexible connector passes between the flotation module and inertial mass.
  • a flexible connector also passes between the flotation module and the restoring weight. In some cases, these are one and the same flexible connector; in other cases, the flexible connector passing to the inertial mass is distinct from the flexible connector passing to the restoring weight.
  • the flexible connector is "ribbon-like" (sometimes referred to simply as a "ribbon”).
  • the flexible connector includes a plurality of separate “strands,” each of which might be, for instance, an independent segment of wire rope.
  • the separate strands are arranged to form a flat connector having a combined tensile strength approximately equal to the sum of the tensile strengths of the constituent strands, but collectively more suitable for transiting around a rotary member such as a pulley/capstan.
  • the D/d ratio can be made larger, without having to resort to a pulley/capstan of enormous proportions.
  • the combined friction induced from a ribbon onto the pulley/capstan is approximately equal to the sum of the friction induced from the constituent strands, but collectively more suitable for rotating the pulley/capstan.
  • the separate strands that constitute the ribbon-like flexible connector terminate at, or otherwise affix to, a common rigid connector or "junction" located at an intermediate point along the flexible connector.
  • a common rigid connector or "junction” located at an intermediate point along the flexible connector.
  • the multiple strands of the ribbon each transmit a tensile load to the rigid structure of the connector/junction. From this junction then can proceed another portion of the flexible connector, perhaps a unitary wire rope, spanning a further distance of the flexible connector.
  • the converter further incorporates at least one slack-reducing element whose purpose is to ensure that when the distance between the inertial mass and flotation module decreases, any momentary slack in the at least one flexible connector is taken up rapidly, or to put it a different way, to ensure that no significant slack accumulates in the flexible connector.
  • the at least one slack-reducing element can incorporate at least one restoring weight or restoring float attached to a portion of the flexible connector opposite the portion attached to the inertial mass, configured to draw the flexible connector back over the rotating capstan or pulley when the separation distance between flotation module and inertial mass decreases.
  • At least one slack- reducing element is at least one generator or motor, configured to "rewind" the at least one flexible connector.
  • the at least one slack-reducing element can include at least one slack-reducing motor separate from the at least one main generator.
  • the at least one slack-reducing element can include a hydraulic accumulator that stores energy in the form of a compressed gas to rewind the flexible connector.
  • the net (wet) weight of the restoring weight is smaller, usually significantly smaller, than the net (wet) weight of the inertial mass. In some embodiments, the net (wet) weight of the restoring weight is one ninth the net (wet) weight of the inertial mass.
  • a hydraulic system is used to transmit mechanical power from a rotating pulley/capstan to an electrical generator.
  • at least one pulley/capstan rotates due to a torque applied by a flexible connector.
  • the rotating pulley/capstan is connected to a crankshaft, camshaft, or other similar mechanical structure (hereafter, "crankshaft”).
  • the crankshaft is connected to an assembly of hydraulic cylinders.
  • the rotation of the pulley/capstan causes the hydraulic cylinders to pump hydraulic fluid at high pressure.
  • the high pressure hydraulic fluid is routed to a hydraulic motor or turbine (such as a Pelton wheel).
  • the hydraulic motor or turbine drives an electrical generator.
  • the pulley/crankshaft assembly described above is repeated multiple times, so that there are multiple pulleys/capstans, each with its own mechanical assembly such as a crankshaft for transforming rotational motion into linear motion in an assembly of cylinder pistons.
  • each of the pulley/crankshaft assemblies is associated with its own hydraulic motor or turbine, and with its own electrical generator, so that there are multiple hydraulic motors/turbines, and multiple electrical generators.
  • a rotary piston pump, or rotary piston motor configured to be operated as a pump, is used in lieu of a crankshaft/cylinder assembly, to translate rotary motion of the pulley/capstan into pressure in the hydraulic fluid.
  • a hydraulic accumulator is utilized in the one or more hydraulic circuits to provide a power-buffering and power-storage function.
  • hydraulic fluid falling from a hydraulic turbine (such as a Pelton wheel) after striking said turbine collects in a reservoir and lubricates aforementioned crankshaft.
  • a gearbox is used to convert low-rpm rotary motion of the capstan/pulley into high-rpm rotary motion for an electrical generator shaft.
  • some parts of the power-take-off system are incorporated within a discrete, removable module for maintenance.
  • a plurality of hydraulic cylinders are included in a removable module.
  • At least one flywheel, pneumatic or hydraulic accumulator, or other mechanical energy storage system incorporated within the power-take-off system can buffer and/or smooth the mechanical inputs to the generator, so that they do not occur solely during, or are not so greatly concentrated during, the portions of the mechanical cycle when the inertial mass is being accelerated upward.
  • a challenge is maintaining favorable "fleet angles" for the converter's flexible connector(s).
  • a fleet angle can be defined as the angle of incidence of a flexible connector to the pulley sheave with which it is associated, or, more precisely the angle of incidence of a flexible connector to a pulley's plane of rotation (a plane normal to a pulley's axis of rotation), relative to the optimal or nominal design angle. Too large of a fleet angle can cause mechanical stresses and failure modes such as abrasion of the flexible connector and/or wear of the mechanical components of the power-take-off system. We have devised two classes of improvement to provide for consistently satisfactory fleet angles.
  • a first class of improvements involves the use of a "direction rectifying flotation module.”
  • a direction rectifying flotation module is one whose shape and center of mass are selected to allow the flotation module to rotate relatively freely in the water, at least when the flotation module's orientation is within certain angular limits.
  • the flotation module is neutrally stable, marginally stable, or marginally unstable, again, at least when its orientation is within certain angular limits (e.g. rotated no more than 20 degrees from its nominal orientation).
  • a direction rectifying flotation module has a shape and mass distribution chosen to provide a small or zero restoring moment within certain angular bounds, so that the flotation module can be induced to rotate in the water with a relatively small force/torque, and so that waves in the water induce little if any pitch and/or roll, even if large and highly sloped.
  • the location(s) of the at least one pulley/capstan is/are chosen so that they can (collectively, if applicable) apply a torque to the flotation module to rotate it under certain circumstances, particularly at times when a large tension exists in the flexible connector, to correct for any fleet angle misalignments.
  • the preferred flotation module form having these properties is one wherein the bottom surface of the flotation module has a shape approximating that of an inverted "spherical dome" - i.e. has a curvature like a segment or arc of a sphere.
  • the equipment and hull of the flotation module are arranged so that the center of mass of the flotation module is near the geometric center of the sphere approximately defined by the aforementioned sphere-like bottom surface of the flotation module. In some such embodiments, the center of mass is within 20% of one radius from the geometric center of the sphere approximately defined by the aforementioned sphere-like bottom surface of the flotation module. In some embodiments, the bottom of the flotation module has a shape
  • a flotation module need not have a precisely spherical or cylindrical bottom surface in order to fall within the scope of the current disclosure.
  • At least one pulley/capstan is located at a bottom portion of the flotation module, so that a tension in the flexible connector causes a nominal vertical axis of the flotation module to rotate into closer alignment with a line passing through the flotation module and the inertial mass.
  • a plurality of pulleys/capstans are spaced from the center of the flotation module, e.g. at an outer circumference thereof, and are controlled to collectively apply a torque that rotates the flotation module into closer alignment with a line passing through the flotation module and the inertial mass.
  • the direction rectifying flotation module uses the fact that an appropriately shaped floating object can behave as if it is on a highly effective "ball joint", "gimbal", or bearing by using the water itself as the bearing surface. If a flotation module with a requisite "circular" shape (e.g.
  • hemispherical, spherical, cylindrical, hemi-cylindrical is paired with power take off units mounted at its bottom portion, or some horizontal distance from its center, e.g. at its horizontal periphery, such that these power take off units can collectively apply a net torque to the flotation module, either passively when a tension increases in the flexible connector, or under the influence of a control system or mechanical governor; then the flotation module will be consistently oriented so that its "inertial mass alignment axis" (or “vertical axis”) points toward the inertial mass (at least approximately). This design strategy significantly reduces the "fleet angle problem.”
  • the flotation platform a circular or arc-like cross section in at least one vertical "reduced- stability plane" (e.g. by giving it a hemispherical or hemi- cylindrical shape, or a cylindrical or hemi-cylindrical shape, or other 3D shape having a 2D circular or arc-like cross section in at least one vertical plane), and preferably we place the center of mass of the flotation module relatively close to a hydrostatic "metacenter" of a said circular or arc-like profile, i.e. relatively close to an axis around which the flotation module's center of buoyancy will tend to rotate.
  • a hydrostatic "metacenter" of a said circular or arc-like profile i.e. relatively close to an axis around which the flotation module's center of buoyancy will tend to rotate.
  • a flotation module with said shapes is relatively hydrostatically unstable in said at least one "reduced- stability plane.” This hydrostatic instability entails that the flotation module experiences relatively little buoyant restoring moment/torque about at least one horizontal axis, no matter the wave conditions.
  • the flotation module's tendency to pitch and/or roll due to forces from waves is significantly reduced, if not eliminated, at least in the relevant vertical plane(s).
  • a flotation module with this sort of reduced stability or (at least partially) unstable hydrostatic profile requires relatively little torque to cause it to rotate in the water to any desired angle, at least in the relevant vertical plane or planes, at least within a predetermined range of angles.
  • the flotation module's pitch and roll can then be controlled and regulated to help solve the fleet angle problem.
  • the flotation module's pitch and roll are regulated using the power take off units mounted on the flotation module, preferably some horizontal distance from the platform's lateral center.
  • the platform' s pitch and roll can be regulated by varying the tension in some flexible connectors relative to others, and/or by varying the torque or force applied by some power take off units relative to that applied by others. Owing to these differential forces/tensions, the flotation module experiences a torque, and can be rotated so that its relevant "inertial mass alignment axis" points toward the inertial mass.
  • no active control is required, because the power-take-off pulley(s) are located at a bottom portion of the flotation module. Note that when the flotation module has the shape of a sphere or hemisphere (or other segment or section or other fraction of a sphere), the flotation module can be stable, neutrally stable, or unstable in all vertical planes.
  • the receptiveness of the flotation module to a fleet-angle- correcting (i.e. to a "direction rectifying") torque or moment can be measured and quantified by the value of, a ratio involving, its metacentric height, determined with reference to at least one vertical cross section.
  • a metacentric height is a well-known measure of the stability of a floating object. Typically in the construction of floating structures it is desirable to maximize a metacentric height or at least ensure that it is within a range of positive values having sufficiently large magnitude.
  • the metacentric height in question is the geometric metacentric height and/or the metacentric height in the flotation module's nominal equilibrium orientation.
  • a metacentric height of the flotation module is less than a distance between (i) the flotation module's center of mass and (ii) a pulley mounted at a bottom portion of the flotation module.
  • a metacentric height of the flotation module is less than a distance between (i) the geometric center of the smallest enclosing spherical hull that would fit around the flotation module and (ii) a pulley mounted at a bottom portion of the flotation module.
  • a metacentric height of the flotation module is less than one half of a radius (or less than one half of a half-width) of the flotation module.
  • the receptiveness of the flotation module to a fleet-angle- correcting torque or moment can be measured and quantified by the ratio of a hydrostatic restoring moment of the flotation module to a direction-rectifying moment applied by the flexible connector, the latter preferably being greater than the former.
  • rollers it is preferable to locate multiple rollers at a bottom portion of the flotation module.
  • the fleet angle problem is addressed through the use of auxiliary "direction rectifying pulleys" that are each free to rotate about a relevant axis to ensure that the fleet angle to each direction rectifying pulley is minimized.
  • auxiliary direction rectifying pulleys are necessary to address the fleet angle problem. A cable passing over and through a direction rectifying pulley, and then onto a pulley of the power take-off system will always be presented to the pulley of the power take-off system at an approximately perfect fleet angle, thus maximizing the lifetime of both.
  • the flotation module can be broad and flat, like a pancake, or can have other shapes providing advantageous hydrostatic, hydrodynamic, or structural characteristics.
  • individual direction rectifying pulleys are configured to rotate about an axis that is nearly collinear with the top groove of a power-take-off pulley with which the individual direction rectifying pulley is associated.
  • the device is configured with suspended weights, metal chains, and/or metal ropes disposed so that when the inertial mass is controlled to rise in the water column (decreasing both its depth and its separation distance to the flotation module), the inertial mass unavoidably "picks up,” and supports a greater fraction of the net weight of, said suspended weights, chains, and/or ropes, than it did when it was at a greater depth.
  • the effective net weight of the inertial mass increases as its depth decreases; this allows for a greater magnitude of gravitational force to act on the inertial mass, especially when, in the course of its oscillations, it falls under gravity; this in turn can impart a greater momentum to the inertial mass and allow more power to be generated from a given sea state, assuming of course that the energy in the sea state does in fact support the dynamic suspension of an inertial mass having the effective net weight in question.
  • the aforementioned suspended weights, metal chains, and/or metal ropes act on the inertial mass by depending from a bottom portion thereof. In some embodiments, the aforementioned suspended weights, metal chains, and/or metal ropes act on the inertial mass by draping against a top portion thereof. In some embodiments, the aforementioned suspended weights, metal chains, and/or metal ropes act on the inertial mass by accumulating in an interior portion or receptacle thereof.
  • a tether is provided: (i) between (a) the restoring weight and (b) the inertial mass, or (ii) between (a) the restoring weight and (b) a portion of the flexible connector disposed between the flotation module and the inertial mass, or (iii) between (a) a portion of the flexible connector disposed between the restoring weight and the flotation module and (b) the inertial mass, or (iv) between (a) a portion of the flexible connector disposed between the restoring weight and the flotation module and (b) a portion of the flexible connector disposed between the flotation module and the inertial mass.
  • the flexible connector "loops back on itself and provides for a means of arresting the fall of the inertial mass even in the absence of waves and/or in the event that the power-take-off unit ceases applying a lifting force to the inertial mass.
  • the device when the inertial mass falls downward, moving outside of an operational separation distance range in which it previously oscillated, the device is configured so that weights and/or metal chains and/or metal ropes (and/or segments of metal chains and/or metal ropes) that previously depended from the inertial mass (at least predominantly), and that previously added their net or wet weight to that of the inertial mass, are instead "picked up” by, and shift their gravitational weight to (at least predominantly) one or more of the following: (i) a flexible connector containing, or depending from, the restoring weight, or (ii) a flexible connector depending directly from the flotation module. Accordingly, the effective net weight of the inertial mass decreases as its depth increases; and in some embodiments, the effective net weight of the restoring weight concomitantly increases as the depth of the inertial mass increases.
  • a result of this shifting of weight can be that the inertial mass's gravitational descent can slow and can ultimately cease, especially if weight is effectively added to the restoring weight, and hence acts against the inertial mass's gravitational descent.
  • the inertial mass can experience a "soft landing” and attain a static equilibrium, or “parked,” depth even in the absence of “hard stops” or hard mechanical constrains on its descent.
  • a valvular inertial mass can enable some embodiments of the disclosed converter to reliably and passively assume a "safe mode" configuration in the event of a systems failure and/or upon receipt of a "go to safe mode” command from an operator or control system.
  • the inertial mass In its "safe mode” configuration, the inertial mass can allow significant passage of water through its interior, e.g., along its vertical axis, e.g., across a horizontal plane.
  • An inertial mass in "safe mode” can have an effective mass significantly smaller than its normal (standard operational) effective mass, and hence can offer significantly less resistance than its normal (standard operational) resistance to the upward acceleration of the flotation module.
  • Such a passive "feathering" mechanism has the advantage of allowing the system to shed the energy of a storm even if its normal control systems inadvertently go offline.
  • a "compacted" configuration of some embodiments of the converter can enable safe and efficient transportation and deployment of the converter.
  • FIG. 1 is an elevated perspective view of a first preferred embodiment of the present invention
  • FIG. 2 is a top-down view of the embodiment of FIG. 1;
  • FIG. 3 is a sectional view of the embodiment of FIG. 1;
  • FIG. 4 is a sectional view of the embodiment of FIG.3;
  • FIG. 5 is an enlarged, sectional view of the power-take-off module of FIG. 4;
  • FIG. 6 is a sectional view of the embodiment of FIG.1;
  • FIG. 7 is an enlarged, elevated perspective view the flotation module of FIG.l including post-tensioning bands;
  • FIG. 8 is a perspective top down view of the flotation module of a second preferred embodiment of the present invention.
  • FIG. 9 is a perspective bottom up view of the flotation module of FIG.8;
  • FIG. 10 is a perspective top down view of the flotation module of the embodiment of FIG.8 using partial transparency of the buoy walls to facilitate examination of the power-take-off assemblies therein;
  • FIG. 11 is a perspective top down view of the power-take-off assemblies of the flotation module of FIG. 10;
  • FIG. 12 is a perspective top down view of one of the four power-take-off assemblies of the flotation module of FIGS.8-10;
  • FIG. 13 is a perspective bottom up view of a portion of one of the four power-take- off assemblies of the flotation module of FIGS.8-10;
  • FIG. 14 is a perspective top down view of the flotation module of the embodiment of FIG.8 incorporating an alternate power-take-off design;
  • FIG. 15 is a perspective top down view of the power-take-off of the flotation module of FIG. 14;
  • FIG. 16 is a perspective top down view of one of the four power-take-off assemblies of the flotation module of FIG. 14;
  • FIG. 17 is an elevated perspective view of a third preferred embodiment of the present invention.
  • FIG. 18 is a sectional view of the embodiment of FIG. 17;
  • FIG. 19 is a sectional view of the embodiment of FIG. 18;
  • FIG. 20 is a sectional view of the embodiment of FIG. 19;
  • FIG. 21 is a sectional view of the embodiment of FIG. 20;
  • FIG. 22 is an elevated perspective view of a fourth preferred embodiment of the present invention.
  • FIG. 23 is a top down view of the embodiment of FIG. 22;
  • FIG. 24 is an enlarged, top down view of a power-take-off assembly of the embodiment of FIGS. 22-23;
  • FIG. 25 is an enlarged, side view of the power-take-off assembly of FIG. 24;
  • FIG. 26 is an enlarged view of the opposite side of the power-take-off assembly of FIG. 24;
  • FIG. 27 is a top down view of the embodiment of FIG. 22 where a centralized power- take-off has replaced the individual power-take-offs;
  • FIG. 28 is a top down view of the embodiment of FIG. 22 where the power-take- offs comprise gearboxes instead of hydraulic circuits;
  • FIG. 29 is an elevated perspective view of a fifth preferred embodiment of the present invention.
  • FIG. 30 is a top down view of the embodiment of FIG. 29;
  • FIG. 31 is a sectional view of the embodiment of FIG. 30;
  • FIG. 32 is a side view of the embodiment of FIG. 29;
  • FIG. 33 is a sectional view of an embodiment of the present invention.
  • FIG. 34 is a sectional view of an embodiment of the present invention which comprises a ribbon cable
  • FIG. 35 is a sectional view of an embodiment of the present invention which comprises multiple inertial masses and restoring weights;
  • FIG. 36 is a top down view of the embodiment of the present invention;
  • FIG. 37 is a sectional view of the embodiment of FIG. 36;
  • FIG. 38 is a top down view of the embodiment of the present invention.
  • FIG. 39 is a sectional view of the embodiment of FIG. 38;
  • FIG. 40 shows a chart illustrating a representative pattern of change over time of the separation distance between the buoy and inertial mass of an embodiment of the present invention;
  • FIGS. 41-44 show a series of flow charts corresponding to control systems of the present invention.
  • FIGS. 45-48 show a series of diagrams representing the operational behavior of an embodiment of the present invention.
  • FIG. 49 is an elevated perspective view of an embodiment of the present invention.
  • FIG. 50 is an elevated perspective view of an embodiment of the present invention
  • FIG. 51 is an elevated perspective view of an embodiment of the present invention
  • FIG. 52 is an elevated perspective view of an embodiment of the present invention.
  • FIG. 53 is an elevated perspective view of an embodiment of the present invention.
  • FIG. 54 is an elevated perspective view of an embodiment of the present invention.
  • FIG. 55 is an elevated perspective view of an embodiment of the present invention
  • FIG. 56 is an elevated perspective view of an embodiment of the present invention
  • FIG. 57 is an elevated perspective view of an embodiment of the present invention.
  • FIG. 58 is an elevated perspective view of an embodiment of the present invention.
  • FIG. 59 is an elevated perspective view of a pulley illustrating a cable engaging the pulley
  • FIG. 60 is an elevated front view of the pulley in FIG. 59;
  • FIG. 61 is an elevated front view of the pulley in FIG. 59 in which the cable is engaging the pulley at an angle outside the plane of the pulley's rotation;
  • FIGS. 62-67 are diagrams illustrating the change in the orientation of a cable connecting a buoy to an inertial mass as the buoy moves in response to passing waves
  • FIG. 68 is a diagram illustrating the change in the orientation of a buoy that would be required in order to maintain an optimal fleet angle between a pulley on the buoy and a cable connecting the pulley to an inertial mass as the buoy moves in response to passing waves;
  • FIG. 69 is a diagram illustrating the utility of a buoy with a circular hull cross- section in maintaining a buoy orientation conducive the maintenance of an optimal fleet angle
  • FIG. 70 is an illustration of a buoy with a circular hull cross-section and with pulleys oriented so as to promote the maintenance of an optimal fleet angle
  • FIG. 71 is a diagram illustrating the reorientation of a buoy to maintain an optimal fleet angle
  • FIG. 72 is a diagram illustrating the preferred location of a buoy's center of mass so that its hull with a circular cross-section will readily reorient itself so as to promote the maintenance of an optimal fleet angle;
  • FIG. 73 is an elevated perspective view of an embodiment of the present invention.
  • FIG. 74 is a top down view of the embodiment of FIG. 73.
  • FIG. 75 is a diagram illustrating the motion of the embodiment of FIG. 73 in response to passing waves
  • FIG. 76 is an elevated perspective view of an embodiment of the present invention.
  • FIG. 77 is a top down view of the embodiment of FIG. 76.
  • FIG. 78 is an elevated perspective view of an embodiment of the present invention
  • FIG. 79 is a sectional view of the embodiment of FIG. 78.
  • FIG. 80 is an elevated perspective view of an embodiment of the present invention.
  • FIG. 81 is a diagram illustrating the motion of the embodiment of FIG. 80 in response to passing waves from a side perspective.
  • FIG. 82 is a diagram illustrating the motion of the embodiment of FIG. 80 in response to passing waves from a front perspective.
  • FIG. 83 is a top down view of the embodiment of FIG. 80.
  • FIG. 84 is an elevated perspective view of an embodiment of the present invention.
  • FIG. 85 is a diagram illustrating the motion of the embodiment of FIG. 84 in response to passing waves from a front perspective.
  • FIG. 86 is a diagram illustrating the motion of the embodiment of FIG. 84 in response to passing waves from a side perspective.
  • FIG. 87 is a top down view of the embodiment of FIG. 84.
  • FIG. 88 is an elevated side view of a directional rectifying pulley engaging a cable
  • FIG. 89 is an elevated front view of the directional rectifying pulley in FIG. 88;
  • FIG. 90 is an elevated front view of the directional rectifying pulley in FIG. 88 in which the pulley's angular orientation has changed to as to maintain an optimal fleet angle;
  • FIG. 91 is an sectional view of an embodiment of the present invention.
  • FIG. 92 is an sectional view of an embodiment of the present invention.
  • FIG. 93 is an elevated perspective view of an embodiment of the present invention.
  • FIG. 94 is an elevated side view of the embodiment of FIG. 93.
  • FIG. 95 is an elevated top down view of the embodiment of FIG. 93.
  • FIG. 96 is an enlarged top down view of the flotation module of the embodiment of FIG. 93.
  • FIG. 97 is an elevated perspective view of an embodiment of the present invention
  • FIG. 98 is an elevated perspective view of the embodiment of FIG. 97
  • FIG. 99 is an elevated perspective view of the embodiment of FIG. 97
  • FIG. 100 is an elevated perspective view of the embodiment of FIG. 97 in which a chain has been substituted for the linked restoring weights.
  • FIG. 101 is an elevated perspective view of an embodiment of the present invention.
  • FIG. 102 is an elevated perspective view of an embodiment of the present invention.
  • FIG. 103 is an elevated perspective view of the embodiment of FIG. 102.
  • FIG. 104 is an elevated perspective view of an embodiment of the present invention.
  • FIG. 105 is an elevated perspective view of an embodiment of the present invention.
  • FIG. 106 is an elevated perspective view of an embodiment of the present invention.
  • FIG. 107 is a top down perspective view of the embodiment of FIG. 106.
  • FIG. 108 is a bottom up perspective view of the embodiment of FIG. 106.
  • FIG. 109 is a top down perspective view of the embodiment of FIG. 106.
  • FIG. 110 is a top down perspective view of the embodiment of FIG. 106.
  • FIG. 111 is a bottom up perspective view of the embodiment of FIG. 106.
  • FIG. 112 is an elevated perspective view of an embodiment of the present invention.
  • FIG. 113 is an elevated perspective view of the embodiment of FIG. 112;
  • FIG. 114 is an elevated perspective view of an embodiment of the present invention.
  • FIG. 115 is an elevated perspective view of the embodiment of FIG. 114;
  • FIG. 116 is an elevated perspective view of an embodiment of the present invention.
  • FIG. 117 is an elevated perspective view of the embodiment of FIG. 116;
  • FIG. 118 is a side view illustration of a roller pulley around which a ribbon cable is engaged.
  • FIG. 119 is an elevated perspective view of the roller pulley of FIG. 118;
  • FIG. 120 is a side view illustration of a roller pulley around which a ribbon cable is engaged.
  • FIG. 121 is an elevated perspective view of the roller pulley of FIG. 120;
  • FIG. 122 is a top down perspective view of an embodiment of the present invention.
  • FIG. 123 is sectional perspective view of the embodiment of FIG. 122;
  • FIG. 124 is a side view illustration of a ribbon cable
  • FIG. 125 is a side view illustration of a ribbon cable
  • FIG. 126 is a side view illustration of a ribbon cable
  • FIG. 127 is a side view illustration of a ribbon cable
  • FIG. 128 is a side view illustration of a ribbon cable
  • FIG. 129 is a side -by-side illustration of a buoy flexibly connected to a submerged inertial mass by a pair of vertical cables.
  • FIG. 130 is a side -by-side illustration of a buoy flexibly connected to a submerged inertial mass by a pair of vertical cables that are interconnected at a single central pick point.
  • FIG. 131 is a top down perspective view of an embodiment of the present invention
  • FIG. 132 is sectional perspective view of the embodiment of FIG. 131;
  • FIG. 133 is a top down perspective view of an embodiment of the present invention.
  • FIG. 134 is sectional perspective view of the embodiment of FIG. 133;
  • FIG. 135 is a top down perspective view of an embodiment of the present invention.
  • FIG. 136 is a top down perspective view of the embodiment of FIG. 135;
  • FIG. 137 is sectional perspective view of the embodiment of FIG. 135;
  • FIG. 138 is a top down perspective view of an embodiment of the present invention.
  • FIG. 139 is a top down perspective view of an embodiment of the present invention.
  • FIG. 140 is a top down view of the embodiment of FIG. 139;
  • FIG. 141 is a side view of the embodiment of FIG. 139;
  • FIG. 142 is a back view of the embodiment of FIG. 139;
  • FIG. 143 is a top down view of an embodiment of the present invention.
  • FIG. 144 is a sectional view of the embodiment of FIG. 143;
  • FIG. 145 is a side perspective view of an embodiment of the present invention.
  • FIG. 146 is an enlarged side perspective view of the inertial mass of the embodiment of FIG. 145;
  • FIG. 147 is a side perspective view of an embodiment of the present invention.
  • FIG. 148 is an elevated side view of the embodiment of FIG. 147;
  • FIG. 149 is another elevated side view of the embodiment of FIG. 147;
  • FIG. 150 is a side perspective view of an embodiment of the present invention.
  • FIG. 151 is an elevated side view of the embodiment of FIG. 150;
  • FIG. 152 is a side perspective view of an embodiment of the present invention.
  • FIG. 153 is an side perspective view of the embodiment of FIG. 152;
  • FIG. 154 is a side perspective view of an embodiment of the present invention.
  • FIG. 155 is a side perspective view of an embodiment of the present invention.
  • FIG. 156 is an side view of the embodiment of FIG. 155;
  • FIG. 157 is an enlarged side perspective view of the "stacked plate” inertial mass of the embodiment of FIG. 156;
  • FIG. 158 is a side view of an embodiment of the present invention.
  • FIG. 159 is a side perspective view of an embodiment of the present invention.
  • FIG. 160 is an enlarged side view of the flexible inertial mass of the embodiment of FIG. 160;
  • FIG. 161 is a side perspective view of an embodiment of the present invention
  • FIG. 162 is a side perspective view of an embodiment of the present invention
  • FIG. 163 is a side perspective view of an embodiment of the present invention
  • FIG. 164 is an enlarged side view of the flexible inertial mass of the embodiment of FIG. 163;
  • FIG. 165 is a side perspective view of an embodiment of the present invention
  • FIG. 166 is an enlarged side view of the flexible inertial mass of the embodiment of FIG. 163;
  • FIG. 167 is a sectional side view of an embodiment of the present invention.
  • FIG. 168 is a sectional side view of an embodiment of the present invention
  • FIG. 169 is an enlarged top down view of the inertial mass of the embodiment of FIG. 169;
  • FIG. 170 is a sectional side view of an embodiment of the present invention.
  • FIG. 171 is an enlarged sectional side view of the flotation module of the embodiment of FIG. 170;
  • FIG. 172 is an enlarged perspective side view of the one-way valve in the inertial mass of the embodiment of FIG. 170;
  • FIG. 173 shows a series of diagrams representing the operational behavior of an embodiment of the present invention
  • FIG. 174 is a top down view of an embodiment of the present invention
  • FIG. 175 is a sectional side view of the embodiment of FIG. 174;
  • FIG. 176 is an enlarged bottom up view of the flotation module of the embodiment of FIGS. 174-175;
  • FIG. 177 is an enlarged top down view of the inertial mass of the embodiment of FIGS. 174-175;
  • FIG. 178 is a side sectional view of an embodiment of the present invention.
  • FIG. 178 is a side sectional view of an embodiment of the present invention.
  • FIG. 179 is a side sectional view of an embodiment of the present invention.
  • FIG. 180 is a side sectional view of an embodiment of the present invention.
  • FIG. 181 is an enlarged top down view of the inertial mass of the embodiment of
  • FIG. 180
  • FIG. 182 is a top down view of an embodiment of the present invention.
  • FIG. 183 is side sectional view of the embodiment of FIG. 182;
  • FIG. 184 is a top down view of an embodiment of the present invention
  • FIG. 185 is side sectional view of the embodiment of FIG. 184;
  • FIG. 186 is a top down view of a flotation module of an embodiment of the present invention.
  • FIG. 187 is side sectional view of the embodiment of FIG. 186; and, FIG. 188 is a side perspective view of an embodiment of the present invention.
  • FIG. 189 is a side sectional view of an embodiment of the present invention.
  • FIG. 190 is a side sectional view of an embodiment of the present invention.
  • FIG. 191 is a side sectional view of an embodiment of the present invention.
  • FIG. 192 is a top down sectional view of the embodiment of FIG. 191;
  • FIG. 193 is a side sectional view of an embodiment of the present invention.
  • FIG. 194 is a side sectional view of an embodiment of the present invention.
  • FIG. 195 is a side sectional view of an embodiment of the present invention.
  • FIG. 196 is a side sectional view of a flotation module of an embodiment of the present invention
  • FIG. 197 is a top down sectional view of the embodiment of FIG. 196;
  • FIG. 198 is a side sectional view of an embodiment of the present invention.
  • FIG. 199 is a side sectional view of an embodiment of the present invention.
  • FIG. 200 is a side sectional view of an embodiment of the present invention.
  • FIG. 201 is a top down sectional view of the embodiment of FIG. 200;
  • FIG. 202 is a side sectional view of the embodiment of FIG. 201;
  • FIG. 203 is a side sectional view of an embodiment of the present invention.
  • FIG. 204 is a side perspective view of an inertial mass of an embodiment of the present invention
  • FIG. 205 is a side perspective view of an inertial mass of an embodiment of the present invention
  • FIG. 206 is a side perspective view of a collapsible inertial mass of an embodiment of the present invention in a collapsed configuration
  • FIG. 207 is a side perspective view of a collapsible inertial mass of an embodiment of the present invention in a deployed configuration
  • FIG. 208 is a top down view of an embodiment of the present invention.
  • FIG. 209 is a side sectional view of the embodiment of FIG. 208.
  • FIG. 210 is a side sectional view of an embodiment of the present invention.
  • FIG. 211 is a side perspective view of an embodiment of the present invention.
  • FIG. 212 is a side perspective view of a flotation module of an embodiment of the present invention.
  • FIG. 213 is a side sectional view of the embodiment of FIG. 212;
  • FIG. 214 is a top down sectional view of the embodiment of FIG. 213;
  • FIG. 215 is a side perspective view of a flotation module of an embodiment of the present invention.
  • FIG. 216 is a top down horizontal sectional view of the embodiment of FIG. 215;
  • FIG. 217 is a side sectional view of the embodiment of FIG. 216;
  • FIG. 218 is a side perspective view of a flotation module of an embodiment of the present invention.
  • FIG. 219 is a top down horizontal sectional view of the embodiment of FIG. 218;
  • FIG. 220 is a side sectional view of the embodiment of FIG. 219;
  • FIG. 221 is a side perspective view of a flotation module of an embodiment of the present invention
  • FIG. 222 is a top down horizontal sectional view of the embodiment of FIG. 221;
  • FIG. 223 is a side sectional view of the embodiment of FIG. 222;
  • FIG. 224 is a side perspective view of a flotation module of an embodiment of the present invention
  • FIG. 225 is a top down view of a flotation module of an embodiment of the present invention
  • FIG. 226 is a side sectional view of the embodiment of FIG. 225;
  • FIG. 227 is a side sectional view of the embodiment of FIG. 225;
  • FIG. 228 is a top down sectional view of the embodiment of FIG. 227;
  • FIG. 229 is a side perspective view of a flotation module of an embodiment of the present invention;
  • FIG. 230 is a side perspective view of a flotation module of an embodiment of the present invention.
  • FIG. 231 is a top down view of the embodiment of FIG. 230;
  • FIG. 232 is a side sectional view of the embodiment of FIG. 231 ;
  • FIG. 233 is a top down sectional view of the embodiment of FIG. 232;
  • FIG. 234 is a side perspective view of a flotation module of an embodiment of the present invention.
  • FIG. 235 is a side sectional view of the embodiment of FIG. 234;
  • FIG. 236 is a side perspective view of a flotation module of an embodiment of the present invention;
  • FIG. 237 is a side sectional view of the embodiment of FIG. 236;
  • FIG. 238 is a top down view of a flotation module of an embodiment of the present invention.
  • FIG. 239 is a top down view of a flotation module of an embodiment of the present invention.
  • FIG. 1 shows a side view of an embodiment of the present disclosure.
  • a buoyant structure i.e. a “buoy” or “flotation module”
  • Housed within the buoy 1 is a "power-take- off (or “PTO") module 6A, 6B, and 7 which contains rollers (pulleys) which interact rotatably with sets of cables, e.g. 11 and 17, organized as parallel “ribbons.”
  • An upper portion 6A of the PTO module is above the upper surface 1 of the buoy, while a lower portion 6B of the PTO module protrudes into the water.
  • the rollers inside the lower portion 6B of the PTO module are typically fully submerged, as are the ribbons rotatably attached to them.
  • rollers and their respective cables provide advantages with respect to the control and prevention of corrosion within those rollers and their respective ribbons. For instance, when fully submerged a steel roller or cable can typically be adequately protected from corrosion by sea water through the imposition of an impressed current or the placement of sacrificial anodes in a connected circuit. By contrast, when only intermittently submerged, and/or periodically dry, the ability to resist corrosion in steel members can be more difficult and/or less successful.
  • One end, e.g. 20, of each ribbon is connected to a chain 19 or "restoring weight.”
  • the other end, e.g. 14, of each ribbon is connected to a negatively-buoyant structure 10, i.e. to an "inertial mass.”
  • the "wet weight" of the chain 19 is less than the wet weight of the inertial mass, so that in the absence of wave-induced lifting of the buoy, and an associated pulling up of the portion of the ribbons connecting the buoy to the inertial mass, the inertial mass would tend to sink under its own wet weight, overcoming the upward counterforce imposed by the chain via the ribbon.
  • Each of the embodiment' s rollers is rotatably connected to a crankshaft (not shown) which, in turn, is connected to a set of hydraulic pistons (not shown).
  • the resulting pressurized hydraulic fluid flows through a hydraulic generator or turbine (not shown) which is rotatably connected to a generator (not shown).
  • the PTO module 6 and 7 may be inserted into, and/or removed from, a complementary aperture within the buoy.
  • Narrowing bevels allow the PTO module 6 and 7 to be fully supported within the buoy without the need for, or with a comparatively small number or size of, additional fasteners.
  • Inertial mass 10 is connected to the distal ends of the ribbons, e.g. 15, by and through a mesh 16 composed of inter-connected flexible cables.
  • the inertial mass 10 is an enclosure, chamber, and/or vessel, composed of an outer cementitious wall surrounding an enclosed and/or trapped inner body of water.
  • the hull 5 of the buoy 1 is approximately, if not exactly, hemi- spherical.
  • the buoy tends to rotate so as to preserve a buoy- specific longitudinal axis that is coaxial with the vertical longitudinal axis of the inertial mass, and/or which passes through the inertial mass's center of mass.
  • the bottom of the buoy rotates to point toward the inertial mass, especially when a tension increases in the ribbon cables.
  • each roller is able to "unroll” the portion of its respective ribbon cable that connects it to the inertial mass 10, if its turns in the appropriate direction and at a sufficient rate of turning, power may be extracted from the separation of the buoy 1 from its respective inertial mass 10 by coupling the turning of each roller to the turning of a generator's rotor.
  • a torque on each roller that imparted to each roller's respective ribbon cable a force equal in magnitude, but opposite in direction, to the corresponding force imparted to each roller's respective ribbon cable by the relative movement of the inertial mass away from the buoy, would be expected to stop each roller from turning (by resisting its turning with a torque equal and opposite to the torque imparted to it by its respective ribbon cable) and thereby to stop each ribbon cable from translating/rotating.
  • any "resistive" torque imparted to a roller that is less than the torque imparted to it by the inertial mass will allow the roller to turn, and allow the ribbon cable connecting that roller to the inertial mass to actuate the roller.
  • a generator or power-take-off system such as a hydraulic power take off system that increases a pressure in a fluid to impel said fluid against a hydrokinetic turbine coupled to a generator
  • a generator or power-take-off system such as a hydraulic power take off system that increases a pressure in a fluid to impel said fluid against a hydrokinetic turbine coupled to a generator
  • to impose the oppositional torque to each roller and especially to impose a changing and/or variable degree and/or magnitude of oppositional torque to each roller so that the amount of resistive roller torque remains proportional to, and, at most, only slightly less than, the amount of pulling torque imparted to each roller by the inertial mass, copious amounts of electrical power may be generated.
  • the energy of waves at the surface of a body of water may be converted, at least in part, to electrical power, and/or to some other useful form of energy and/or work, e.g. the compression of air, the desalination of water, the propulsion of the buoyant structure, the synthesis of a chemical fuel, etc.
  • FIGs. 2, 3, and 6, of views taken along lines 2, 3, and 6, respectively.
  • the wet weight of the chain is equal to that of the inertial mass. And, in yet another embodiment similar to the one illustrated in FIG. 1, the wet weight of the chain is greater than that of the inertial mass.
  • the wet weight of the inertial mass 10 is zero, i.e. the inertial mass is neutrally buoyant.
  • the wet weight of the net 16 surrounding the inertial mass 10 is sufficient to cause the inertial mass to sink under the influence of gravity.
  • the restoring weight 19 is replaced with a flexible linked set of negatively-buoyant weights.
  • the single shared restoring weight 19 is replaced with individual, separate weights, and/or sets of weights, that are each attached to a single, particular ribbon end, e.g. 20.
  • the inertial mass 10 encloses and/or contains an additional weight or set of weights to increase its wet weight.
  • the inertial mass 10 is constructed of steel, plastic, metal, stone, water-infused aerogel, and/or other substances, and/or mixtures of substances.
  • Buoyant structure 1 is a floating object which supports, and holds at the surface 4 of a body of water, a PTO module 6 and 7. Through its support of the PTO module, it also indirectly suspends the ribbon cables, e.g. 11, that depend from the module, and the inertial mass 10 that depends from the cables.
  • buoyant structure of this functionally constitute, and might equivalently be referred to as, a "buoy,” “flotation and/or buoyant module,” “floating and/or buoyant platform,” and/or “float.”
  • a principal purpose and/or function of buoyant structure 1 is to hold the embodiment at or adjacent to the surface 4 of a body of water and transmit a periodic lifting force to the inertial mass.
  • Each "ribbon cable,” e.g. 11, is a set of individual cables, chains, ropes, and/or other flexible connectors or linkages, which are organized as a bundle, preferable in a "flat" configuration in which the individual cables within a bundle are arrayed in a planar pattern.
  • Such a flat configuration may facilitate the passage of each such ribbon cable over and/or around its respective roller, e.g. each individual cable passing over and/or around its own approximately circumferential grooves within the surface of its respective roller, especially grooves following a spiraling contour along the surface of the roller.
  • the ribbon cable of this, and of the other embodiments described in this disclosure functionally constitute, and might equivalently be referred to as, a "cable,” “ribbon,” “belt,” “strap,” and/or flexible connector.
  • the flexible connectors, and/or ribbons, and/or ribbon cables, of this and of the other embodiments described in this disclosure may be composed and/or fabricated of: chains, ropes, steel cables, belts, roller chains, linkages, synthetic cables, gear belts, v- belts, synchronous timing belts, drive belts, pulley belts, and/or any other flexible relatively long, and relatively narrow, cord.
  • the ribbon cables, e.g. 11, are actually integral flat flexible connectors and/or belts.
  • belts are sometimes referred to as, and/or composed and/or fabricated of: “belts,” “timing belts,” “v-belts,” “synchronous timing belts,” “drive belts,” “pulley belts,” and/or any other flexible relatively long, and relatively flat, fabric or polymer or composite member.
  • the "wet weight” of a restoring weight or an inertial mass refers to the weight of the restoring weight or inertial mass, less the weight of the water that it displaces.
  • the "wet weight” of an object is the "net” weight of the object when submerged, and represents or is proportional to the degree to which it will tend to sink within a body of water.
  • FIG. 2 shows a "bottom-up" view of the buoy 1 of the embodiment illustrated and discussed in relation to FIG. 1.
  • the PTO module 6B-6C extends through the bottom of the buoy's hull.
  • four rollers e.g. 21.
  • Each roller spins about a shaft, e.g. 22- 23, or axle, that extends through a vertical wall of the PTO module, thus penetrating the walls that separate the interior of the PTO module from the water on which the buoy 1 floats.
  • FIG. 3 shows a cross-sectional view of the embodiment illustrated and discussed in relation to FIGs. 1 and 2, and taken across section line 3 in FIG. 1.
  • This illustration omits the inertial mass connected to the distal ends of the ribbon cables, e.g. 12 and 13. It also omits the restoring weight, i.e. the chain, connected to the ends of the outermost ribbon-cable portions, e.g. 17, 18, and 27.
  • a buoy 1 has a hemi-spherical hull 5, which promotes its turning of its longitudinal axis with respect to its nominal vertical orientation so as to keep its longitudinal axis, and the ribbon cables connecting it to the submerged inertial mass (10 in FIG. 1) aligned, i.e. so as to minimize the degree to which, and the duration during which, the vertical axis of the buoy fails to pass through the inertial mass' approximate center of mass, or, put differently, the bottom of the buoy fails to point at the inertial mass.
  • the buoy is composed, at least in part, of a cementitious material, e.g. cement or concrete, and has been fabricated through a 3D-printing process.
  • This process has resulted in the creation of a cementitious buoy 1 that contains approximately spherical voids, e.g. 26, as well as a strong and/or reinforced aperture in which the PTO module 6A, 6B, 6C, 7, and 8, has been placed, and is seated.
  • the reduction in the module's cross-sectional area, e.g. at inflection point 8, allows the PTO module to enter the aperture in the buoy from above, but not to pass through the buoy.
  • the bottom-most portion of the PTO module 6B and 6C contains walls that separate the interior space within the module from the water below the buoy. However, those walls also create a cross- or x-shaped space at the bottom end of the module that is open to the water.
  • Four rollers, e.g. 21A and 28, are positioned within this cross-shaped space and are typically fully-submerged during the embodiment's operation.
  • a ribbon cable engages each roller, and is thereby rotatably connected to each respective roller.
  • constituent cables of the ribbon cable each wind multiple times around their respective rollers.
  • these constituent cables are each fixedly attached to its respective roller at at least one location on said roller.
  • each ribbon cable portion e.g. 12, lengthen so as to preserve the connection between the buoy and the inertial mass.
  • the forceful paying out of the portion of each ribbon cable, e.g. 13, that connects the buoy to the inertial mass results in a turning of the respective rollers, e.g. 21 A, and a corresponding shortening of the other respective portion of each ribbon cable, e.g. 18 to which the shared restoring weight (19 in FIG. 1) is attached, is accomplished through a turning of each respective roller, e.g. 28, about its axle or shaft.
  • the axle or shaft of each roller penetrates the wall of the PTO module 6B and 6C is connected to a respective crankshaft. As each roller turns, its corresponding crankshaft turns.
  • Each crankshaft contains a number of “crank axles” or “crank throws,” i.e. short axles radially displaced from the primary crankshaft, such that when the crankshaft turns, each crank axle moves along an approximately circular path.
  • the rotational axis of each crank axle is not coaxial with the rotational axis of its respective crankshaft.
  • Each crank axle is rotatably connected to a "driving rod,” e.g. 29.
  • Each driving rod is an approximately straight, rigid rod, bar, strut, or other elongate structural element, one end of which engages with its respective crank axle.
  • the other end of each driving rod is rotatably or hingably connected to one end of a "connecting rod,” e.g. 31.
  • the other end of each connecting rod is hingably or rotatably connected to the "piston rod" of a hydraulic cylinder or piston, e.g. 32.
  • the hydraulic fluid pressurized by the plurality of hydraulic pistons is pooled and/or combined.
  • the resulting pressurized flow of hydraulic fluid is input to, and turns, a turbine 34.
  • the turbine 34 is rotatably connected to a generator 35 which generates electrical power in response to the turning of the rollers.
  • the buoy is constructed of another material, e.g. steel, and/or is constructed of a mixture of materials. Any buoyant structure, regardless of the materials of which it is made, or the method by which it is fabricated, falls within the scope of the invention herein disclosed.
  • the creation of a buoyant structure of sufficient buoyancy and strength to serve as the buoy in an embodiment of this disclosure may be accomplished by a number of methods, and with a number of materials.
  • the scope of the present disclosure is not limited by the method, design, and/or materials, by and/or through which an embodiment's buoy is fabricated.
  • each strand of each ribbon cable is wound about its respective roller over an extent of approximately 180 degrees (i.e. half a turn). In other embodiments similar to the one illustrated in FIG. 3, each strand of each ribbon cable is wound about its respective roller approximately 540 degrees (i.e. 1.5 turns), 900 degrees (i.e. 2.5 turns), and so on.
  • each strand of each ribbon cable in an embodiment of the present disclosure may be wound around its respective roller by any number of turns.
  • the surfaces over which the ribbon cables are wound, and/or against which they interact with the rollers are approximately flat.
  • the rollers contain circumferential grooves.
  • the rollers contain spiral grooves.
  • the present disclosure includes embodiments with rollers characterized by any circumferential surface configuration, shape, attribute, and/or quality.
  • FIG. 4 shows a cross-sectional view of the embodiment illustrated and discussed in relation to FIGs. 1-3, and taken across section line 4 in FIG. 3 This illustration omits the inertial mass and the restoring weight connected to the ends of the ribbon cables.
  • the walls, e.g. 40 and 41, of the PTO module 6B create a "plus-" or "cross- shaped" enclosure in which are positioned four rollers, e.g. 38, and which is open to the body of water 42 below. These walls, e.g. 41, also isolate portions of the PTO module's interior, keeping those portions separate from the surrounding water. Where the shaft of each roller passes through the wall of the PTO module to interface with the respective crankshaft, a bearing and seal can be provided to limit water ingress and provide for smooth rotation.
  • Each roller e.g. 38, is rotatably connected to a ribbon cable, e.g. 39. As the ribbon cable is pulled up and down by the inertial mass (10 in FIG. 1) and restoring weight (19 in FIG. 1), the cable rolls over its respective roller e.g. 38, thereby turning the roller.
  • Each roller, e.g. 38 spins and/or turns about an axle or shaft, e.g. 44 and 43. While the portions of the roller axles adjacent to the rollers is immersed in the water 42, the distal portions of each axle pass through the PTO module's walls, e.g. on or within bearings 45.
  • a portion of each roller's axle includes a crankshaft, e.g.
  • FIG. 5 shows a cross-sectional view of the PTO module of the embodiment illustrated and discussed in relation to FIGs. 1-4, and taken across section line 5 in FIG. 4. This illustration omits the buoy, the inertial mass, and the restoring weight, as well as all but one of the rollers.
  • ribbon cable 17 As ribbon cable 17 is pulled up and down by the attached inertial mass (10 in FIG. 1) and restoring weight (19 in FIG. 1) it causes the roller 21 to rotate.
  • the rotation of roller 21 causes a corresponding rotation of its respective crankshaft 43 (only a portion of which is within the sectional view).
  • the rotation of the crankshaft 43 causes the rotation of the crankshaft's plurality of crank axles, e.g. 43.
  • the rotation of the crankshaft's crank axles causes the rotatably connected driving rods, e.g. 29, to rotate and/or oscillate within their planes of rotation.
  • the oscillations of the driving rods causes the respective rotatably connected connecting rods, e.g. 31, to oscillate.
  • the connecting rods are only able to oscillate along their longitudinal axes, i.e. to oscillate back-and-forth along an approximately constant longitudinal path.
  • the linear oscillations of the connecting rods cause the respective piston rods, e.g. 50, to which they are rotatably connected, to oscillate linearly, and to drive back and forth their respective piston heads, e.g. 48.
  • the linear oscillations of the piston heads pressurizes and pumps hydraulic fluid (and/or another fluid, e.g. air or water) through a fluid circuit that results in the spinning of a turbine or hydraulic motor and the consequent spinning of a generator rotor and a generation of electrical power.
  • each crank axle is rotatably connected to a driving rod, e.g. 29, which, in turn, is rotatably connected to a connecting rod, e.g. 31, which, in turn, is rotatably connected to a piston rod, e.g. 50, and thereby by an hydraulic piston, e.g. 32.
  • each connecting rod, e.g. 31, spans the walls 51 that separate the PTO module 6 A and 7 into upper 6 A and lower 7 portions and/or sections.
  • the end of each connecting rod, e.g. 31, that connects the connecting rod to its respective driving rod, e.g. 29, remains within the lower section 7 of the PTO module.
  • the other end of each connecting rod, e.g. 31, that connects the connecting rod to its respective piston rod, e.g. 50 remains within the upper section 6A of the PTO module.
  • This division, and/or segregation, of the PTO module into upper and lower sections facilitates the removal, and/or replacement, of that portion of the PTO module containing the hydraulic cylinders.
  • FIG. 6 is a top-down cross-sectional view of the embodiment illustrated and discussed in relation to FIGs. 1-5, and taken across section line 6 in FIG. 1.
  • the sectional view primarily provides a view of the embodiment without the upper wall of the PTO module, thereby allowing an inspection of the associated hydraulic pistons, turbine, and generator therein.
  • Hemi- spherical buoy 1 contains at its center PTO module 6. Visible in the illustration of FIG. 6 is the contents of the upper section of the PTO module 6. A plurality of hydraulic pistons, e.g. 32, are positioned within the module. Indicated in dashed lines are the positions of one of the four rollers 21, and its respective crankshaft 43, located in the lower section of the PTO module, but obscured from direct view by the adjacent pair of walls that separate the upper and lower sections of the PTO module.
  • Each hydraulic piston e.g. piston 5
  • the relative positions, and/or distribution, of the hydraulic cylinders illustrated in FIG. 6 allows for a maximally, or near maximally, separation of the cylinders from one another. This facilitates access to the cylinders, and accommodates their replacement (or upgrade) with cylinders of larger diameter at a future time.
  • the hydraulic fluid pressurized by the hydraulic cylinders is directed into a turbine 34, and the rotational kinetic energy thereby imparted to the turbine, is used to drive an electrical generator 35.
  • FIG. 7 is a side view of an embodiment similar to the one illustrated and discussed in relation to FIGs. 1-6. This illustration omits the inertial mass, and the restoring weight. Unlike the embodiment illustrated in FIGs. 1-6, this embodiment's buoy has been provided with additional radial strength through the inclusion of post- tensioning bands 56-58. These bands constrict the flotation module inward when they are tightened during manufacture. They help to counter the radial and outward forces exerted on the buoy by the PTO module 6A-6B, and 7, at its center, or, put another way, they apply a compressive force to the concrete that works to preemptively offset the concrete being brought into tension (in which mode it would have a tendency to crack).
  • post- tensioning bands 56-58 constrict the flotation module inward when they are tightened during manufacture. They help to counter the radial and outward forces exerted on the buoy by the PTO module 6A-6B, and 7, at its center, or, put another way, they apply a compressive force to the concrete
  • Post- tensioning bands 56-58 can be steel cables and/or synthetic rope cables. At one or more locations around the circumference of the buoy, post-tensioning banks 56-58 can include a mating or tensioning connector so that one end of each band can mate to another end of the same band, and be tightened or tensioned.
  • FIG. 8 shows a perspective view of an embodiment of the current disclosure.
  • Floatation module 501-1 is shown to contain four PTO systems 501-2, four payloads 501-3, and attachment points 501-4.
  • Payloads 501-3 are installed into existing mounts/sockets built into floatation module 501-1. Payloads 501-3 are provided electrical power and status data from flotation module 501-1 via the mounts/sockets they are installed into, e.g. using a data API. The data interface also allows the payloads 501-3 to provide status data and/or computational instructions back to flotation module 501-1 (e.g. to computer systems that form part of the control system of the converter).
  • Attachment points 501-4 can be used for towing, mooring, or mating other lines, cables, chains, or bodies to floatation module 501-1. Attachment points 501-4 can also have electrical interfaces which allow power to be transmitted off or received onto flotation module 501-1.
  • FIG. 9 shows a perspective view of the same embodiment of the current disclosure shown in FIG. 8.
  • Floatation module 502-1 is shown containing four pulleys/capstans (or "drums") 502-5.
  • Drums 502-5 are recessed in and located near the center and bottom of flotation module 502-1.
  • Drums 502-5 can contain grooves/tracks for cables/ropes (a flexible connector) to be constrained within, e.g. one or more spiral grooves.
  • Four drums 502-5 are shown, however more or fewer could be utilized.
  • Motion of the floatation module 502-1 due to displacement of the surface of a body of water it is floating in can cause drums 502-5 to rotate, e.g. when the inertial mass to which the cables/ropes are attached moves in the opposite direction.
  • Flotation module 502- 1 has an approximately hemispherical bottom hull contour to minimize its hydrostatic stability and enable the bottommost portion of the flotation module to rotate freely to point toward the inertial mass when a tension is applied to the drums 502-5.
  • FIG. 10 shows a perspective view of the same embodiment of the current disclosure shown in FIG. 8.
  • Flotation module 503-1 is shown with its shell transparent so internal components can be seen.
  • PTO system 503-2 is shown to include drum 503-5.
  • crankshaft-driven piston assembly 503-6 Connected to drum 503-5 is crankshaft-driven piston assembly 503-6.
  • Assembly 503-6 can be manufactured as an integral unit suitable for installing in the flotation module as unit, e.g. by lowering it into place using a crane.
  • the embodiment shown contains four PTO systems 503-2, however more or fewer could be utilized.
  • the PTO systems are arranged in a circular pattern around a horizontal center of the buoy, each interfacing with one of the drums at a bottom portion of the buoy. In this embodiment, the PTO systems do not share a common mechanical apparatus or hydraulic circuit.
  • FIG. 11 shows a perspective view of the same embodiment of the current disclosure shown in FIG. 8.
  • Floatation module 504- 1 is shown with its upper surface transparent and all other components except the PTO systems 504-2 hidden so internal components can be seen.
  • FIG. 11 shows the orientation of the four PTO systems 504-2 relative to each other.
  • FIG. 12 shows a perspective view of the same embodiment of the current disclosure shown in FIG. 8.
  • FIG. 12 shows detail of PTO system 504-2.
  • Drum 505-5 is rigidly connected to crankshaft 505-8. Rotative motion of drum 505-5 can cause crankshaft 505-8 to rotate within crankcase/fluid reservoir 505-7.
  • Piston connecting rods 505-10 are connected to throws on crankshaft 505-8 and to the rods of pistons 505-11. This linkage assembly is enclosed by crankcase cover 505-9.
  • Six pistons 505-11 are utilized in this embodiment, however more or fewer could be utilized.
  • Rotative motion of crankshaft 505-8 causes the rods of pistons 505-11 to linearly reciprocate.
  • Pistons 505-11 are mounted in piston mount structure 505-12, which is an integral component to the crankshaft-driven piston assembly 503-6.
  • Valving contained in the hydraulic control and filtration container 505- 14 allows the reciprocating motion of the rods in pistons 505-11 to draw fluid from crankcase/fluid reservoir 505-7 and be pumped at high pressure to hydraulic turbine SOS- IS.
  • Accumulators 505-13 maintain fluid pressure and flowrate to turbine 505-15 even if pistons 505-11 stop pumping fluid for a period of time.
  • High pressure fluid driven into hydraulic turbine 505-15 causes turbine 505-15 to rotate.
  • Turbine 505-15 has a shaft which is rigidly connected to the driveshaft of electric generator 505-16. Rotative motion of turbine 505-15 causes the electric generator 505-16 driveshaft to spin, producing electricity.
  • Generator 505-16 is contained within generator housing 505-17. Electricity produced by generator 505-16 passes through electrical conditioning equipment 505-18, which can condition, rectify, convert, step, and/or distribute the electricity as required.
  • FIG. 13 shows a perspective view of the same embodiment of the current disclosure shown in FIG. 8.
  • FIG. 13 shows a different view of PTO system 504-2.
  • the reciprocating motion of the rods of pistons 506-11 draws fluid from crankcase/fluid reservoir 506-7 and pumps it at high pressure into hydraulic turbine 506-15, causing it to rotate. Fluid that has already driven turbine 506-15 returns to crankcase/fluid reservoir 506-7 via fluid return chute 506-19 and through a wall aperture in crankcase cover 506- 9.
  • FIG. 14 shows a perspective view of the same embodiment of the current disclosure shown in FIG. 8.
  • Floatation module 507-20 is shown with its shell transparent so internal components can be seen.
  • PTO system 507-21 is shown to include two instances of crankshaft-driven piston assembly 507-22.
  • Floatation module 507-20 features four PTO systems 507-21, thus eight crankshaft-driven piston assemblies 507-22 are utilized.
  • crankshaft-driven piston assemblies 507-22 Twice as many crankshaft-driven piston assemblies 507-22 can be utilized because each drum 507-23 is attached to two crankshaft-driven piston assemblies 507-22. This is the primary differentiation between this figure and FIG 10, where each drum 503-5 is attached one crankshaft-driven piston assembly 503-6. Details of the single drum/dual crankshaft-driven piston assembly PTO system arrangement are shown in subsequent figures.
  • FIG. 15 shows a perspective view of an embodiment of the current disclosure.
  • Floatation module 508-20 is shown with its upper surface transparent and all other components except the PTO systems 508-21 hidden so internal components can be seen.
  • PTO system 508-21 is shown to include drum 508-23.
  • Drum 508-23 is shown to connect to two instances of crankshaft-driven piston assembly 508-22. In this way, four drums 508-23 are used in floatation module 508-20, connected to eight crankshaft-driven piston assemblies 508-22.
  • FIG. 16 shows a perspective view of an embodiment of the current disclosure.
  • FIG. 16 shows detail of PTO system 508-21. Most of the components are identical in form and function to FIG 12 so only components which are different are described here.
  • Drum 509-23 is rigidly connected to two crankshafts 509-25 via driveshafts 509-24. Rotative motion of drum 509-23 can cause crankshafts 509-25 to rotate within crankcases/fluid reservoirs 509-22.
  • Piston connecting rods 509-26 are connected to throws on crankshaft 509-25 and to the rods of pistons 509-28. This linkage assembly is enclosed by crankcase cover 509-27.
  • crankshaft 509-25 causes the rods of pistons 509-28 to linearly reciprocate.
  • Pistons 509-28 are mounted in piston mount structure 509-29, which is an integral component to the crankshaft-driven piston assembly 508-22.
  • Three pistons 509-28 are utilized per crankshaft-driven piston assembly 508-22 in this embodiment, however more or fewer could be utilized.
  • the fluid pumping action and power generation process utilized in this embodiment is identical to that described in FIG. 12.
  • FIG. 17 shows a side view of an embodiment of the current disclosure.
  • Flotation module 17-1 is floating on the surface of body of water 17-2.
  • the shape of floatation module 17-1 is shown to be nearly hemispherical.
  • Floatation module 17-1 is shown to contain multiple pulleys/rollers/sheaves ("drums") 17-3, which are inset to its outer mold line (“OML”) near the bottom of the flotation module 17-1.
  • Drums 17- 3 may rotate about their cylindrical axis.
  • Passing over and around drums 17-3 are flexible connectors 17-4.
  • Each flexible connector 17-4 is comprised of a linear array of individual ropes/cables/chains, etc.
  • Flexible connectors 17-4 attaches to restoring weights 17-5, which act to keep the flexible connector in tension.
  • Restoring weights 17-5 have a net weight in water which is positive, meaning that they will sink if not attached to anything.
  • Restoring weights 17-5 may be individual weights constructed of concrete, metal, or another material or may also be chains, rope or another flexible component which has a positive net weight in water, particularly chains or ropes of a thicker gauge than those of the ribbon.
  • Flexible connectors 17-4 are commonly attached to confluence 17-6.
  • Confluence 17-6 may be a shackle, swivel, or any one of a multitude of various mechanical hardware. Additional flexible connectors 17-7 are attached to the bottom of confluence 17-6. Additional flexible connectors 17-7 radiate from confluence point 17-6 and support inertial mass (“IM") 17-8. They can interface to IM 17-8 by directly attaching, forming a net to surround it, or by other means. Additional flexible connectors 17-7 may be individual ropes, chains, etc. or may be comprised of multiple flexible connector strands, as is the case for flexible connectors 17-4. IM 17-8 may be constructed of concrete, metal, plastic, or any material strong enough to support internal voids which are filled with water.
  • FIG. 18 shows section cut A-A from FIG 17.
  • Drums 18-3 are shown, however more or fewer could be utilized.
  • Drums 18-3 are supported along their cylindrical axis by shaft 18-9.
  • Shafts 18-9 interface to floatation module 18-1 and allow drums 18-3 to rotate.
  • Flexible connector ribbons 18-4 are shown in cross section and are shown to be conformal to drums 18-3. In some embodiments, the constituent strands of flexible connector ribbons 18-4 are each multiply wound around the associated one of drums 18-3.
  • FIG. 19 shows section cut B-B from FIG 18.
  • a cross section of flotation module 19-1 floating on body of water (“ocean") 19- 2 is shown in this figure.
  • Voids 19-11 are shown to exist in the physical structure of flotation module 19-1. The purpose of voids 19-11 is to minimize the weight of the flotation module 19-1 while leaving sufficient structure to manage and distribute the forces experienced by flotation module 19-1.
  • Void 19-10 is shown to be the space in which drums 19-3 are inset into the OML of floatation module 19-1.
  • Flexible connectors are shown to be the space in which drums 19-3 are inset into the OML of floatation module 19-1.
  • 19- 4 can be seen to be of a ribbon form factor and passing on, around, and over drums 19-3.
  • Restoring weights 19-5 are connected to the ends of flexible connectors 19-4 located closest to the central axis of flotation module 19-1.
  • FIG. 20 shows section cut C-C from FIG 19.
  • a horizontal cross section of flotation module 20-1 is shown in this figure, focusing on the components in and near void 20-10.
  • Void 20-10 is again shown to contain drums 20-3, around which ribbon shaped flexible connectors 20-4 are wrapped.
  • Drums 20-3 are shown to be supported by shaft 20-9, both sides of which interface to flotation module 20-1 and allow drums 20-3 to rotate.
  • One side of shaft 20-9 can interface to gearbox/generator module 20-12.
  • One gearbox/generator module is shown per shaft 20-9, however a gearbox/generator module 20-12 could be utilized on both sides of shaft 20-9. Rotative motion of drum 20-3 causes shafting within
  • gearbox/generator module 20-12 to rotate, subsequently increasing the drum shaft 20-9 RPM and feeding higher RPM rotative motion into a generator within module 20-12 to produce electricity.
  • FIG. 21 shows section cut D-D from FIG 20.
  • a vertical cross section of flotation module 21-1 is shown in this figure, focusing on one of the drums 21-3, and the hardware to which it interfaces.
  • Drum shaft 21-9 extends into the internal structure of flotation module 21-9 and is supported on bearings 21-13 which can also act as a seal against the outside seawater.
  • One side of drum shaft 21-9 can interface to a right-angled gearbox 21-14, which allows the power-take-off drivetrain to be vertically oriented.
  • Output shaft 21-15 extends from right-angled gearbox 21-14 and interfaces to gearbox/generator module 21-12. Rotation of drum 21-3 ultimately results in rotation of internal shafting of gearbox/generator module 21-12, resulting in the production of electricity (as described for FIG 20).
  • Power can be taken off of the rotative motion of the drums 21-3 by applying a countertorque using the generator contained in gearbox/generator module 21-12.
  • a generator is used in this figure to apply countertorque to drums 21-3, and a generator is used to increase shaft RPM, but a hydraulic pump with variable pressure or other system could be utilized.
  • FIG. 22 shows a side view of an embodiment of the present disclosure.
  • a flotation module, or buoy, 130 floats adjacent to a surface 131 of a body of water, and is lifted and allowed to fall in response to passing waves across that surface 131.
  • Buoy 130 is connected to a submerged inertial mass 132 that is approximately spherical.
  • the inertial mass 132 is connected to a pair of cables, e.g. 133, at a point or portion on a net 134 within which the inertial mass is constrained.
  • the cables, e.g. 133, and the net 134 of the inertial mass 132, are joined at an approximately small, single connection point 135.
  • Each cable e.g. 133, rotatably connects to the buoy at a "directional rectifying pulley," e.g. 138, over and/or about which is able to travel with minimal, if any, resistance and/or resistive torque.
  • each directional rectifying pulley is not shafted to a power-take-off unit.
  • Each directional rectifying buoy 138 is mounted to a hollow connecting arm, e.g. 143, which is able to rotate about its longitudinal axis within a bearing 144.
  • Each cable, e.g. 133 passes around its respective directional rectifying pulley, e.g. 138, and through its respective hollow connecting arm, e.g.
  • the directional rectifying pulleys e.g. 138
  • the directional rectifying pulleys are able to rotate about the axes of rotation of their respective hollow connecting arms, e.g. 143, so that their respective cables, e.g. 133, are able to move over and around them while remaining in each pulley's respective plane of rotation (i.e. within a plane normal to each pulley's axis of rotation).
  • the directional rectifying pulleys reduce the wear and damage to their respective cables that would be expected to result from their respective cables' movements around them at excessive "fleet angles," i.e. the angular extent to which a cable enters the groove of a pulley outside of the plane of the pulley's rotation.
  • the directional rectifying pulleys reduce the wear and damage to their respective cables that would be expected to result from their respective cables' movements over the circumferential "edges" of the pulleys.
  • the substantial mass of the inertial mass 132 means that it responds to the upward buoyant forces imparted to it by the buoy with a smaller upward acceleration.
  • the wave-induced tension in the cables may result in the level of the water around the buoy, i.e. in its waterline, rising, potentially overtopping the buoy. It may also result in the cables breaking.
  • those portions, e.g. 133, of the cables between the buoy and the inertial mass will lengthen, simultaneously shortening the portions, e.g. 136, of the cables between the buoy and the restoring weights, e.g. 137.
  • One end of the cables, e.g. 133 are connected to a common junction, connector, and/or point, 135, that connects them to the inertial mass 132.
  • Those cables, e.g. 133 then pass around and/or over a respective directional rectifying pulley, e.g. 138.
  • the "aligned" cables then pass over and around the power-generating pulleys, e.g. 140 and 141.
  • each cable passes over and around a pair of rollers, e.g. 140 and 141, that work together as a "traction winch.”
  • each respective cable, e.g. 139 is able to frictionally engage with the surfaces of the rollers to a degree that tends to minimize slipping and sliding of the cable.
  • circumferential grooves in the surfaces of each roller can allow a respective cable, and/or set of ribbon cables, to pass over and around the rollers without migrating to either side, as would typically occur in relation to a turning spirally-grooved roller.
  • each respective cable After passing over and around the rollers of a traction winch for a certain number of turns, each respective cable travels over and around another pulley, e.g. 142, and then back into the body of water, where it is connected to one or more restoring weights, e.g. 137.
  • At least one roller e.g. 141
  • a crankshaft (not shown) such that as the rollers of the traction winches, e.g. 140-141, are turned in response to the torque imparted to them by their respective cables (i.e. when the buoy is being lifted away from the inertial mass), the crankshaft is rotated which drives a corresponding set of driving rods and connecting rods, which, in turn, drive and/or oscillate the pistons of a set of hydraulic cylinders.
  • This device uses the tension imparted to a pair of cables during the wave- induced separation of the buoy from its connected inertial mass, to turn a pair of traction winches when then pressurize hydraulic fluid and cause a generator to generate electrical power.
  • the amount of upward kinetic and gravitational potential energy imparted to the inertial mass by the buoy can be controlled and/or regulated.
  • the average depth of the inertial mass can be changed, adjusted, and/or controlled (when the waves are sufficiently energetic to permit the buoy to impart sufficient energy to the inertial mass).
  • While different embodiments of the current disclosure may be optimized so as to generate electrical (or other) power from respective inertial masses, each typically and/or preferentially positioned at an embodiment- specific average optimal depth, even a single specific embodiment may change the average depth of its inertial mass in order to adapt and/or optimize its power generation to changing wave conditions, to reduce wear on a particular portion of the cables connecting its buoy to that inertial mass, to avoid a unfavorable current at a particular depth, etc.
  • most embodiments would be expected to benefit from the positioning of their inertial masses such that the average depths of those inertial masses are approximately near or below the wave base characteristic of the wave climate driving those embodiments at any particular time.
  • While the illustrated embodiment utilizes two cables, other embodiments will use multi- stranded ribbon cables. Those embodiments will also use directional rectifying pulleys, and traction-winch rollers, containing sufficient grooves and/or width to accommodate the greater number of parallel strands and/or cables within each respective ribbon cable.
  • FIG. 23 shows a top-down view of an embodiment 130 similar to the one illustrated in FIG. 22.
  • the only difference between the embodiments illustrated in FIGs. 22 and 23 is that the embodiment illustrated in FIG. 23 has eight cables, traction winches, and PTOs, whereas (for the sake of graphical clarity) the embodiment illustrated in FIG. 22 was limited to two cables, traction winches, and PTOs.
  • Eight cables, e.g. 133 connect the buoy to the submerged inertial mass (132 in FIG. 22). Each cable, e.g. 133, passes over and around a directional rectifying pulley, e.g. 138, and then passes through the hollow connecting arm, e.g. 143, that hold each respective directional rectifying pulley and allows it to rotate, by means of a respective bearing, e.g. 144, about the longitudinal and/or rotational axis of its respective hollow connecting arm, e.g. 143.
  • traction winches e.g. 140-141
  • a crankshaft e.g. 148
  • one of the traction-winch rollers e.g.
  • Each crankshaft contains five crank axles, e.g. 150.
  • the rotation of the crankshafts, e.g. 148, causes the respective crank axles to be rotated as well.
  • the rotation of each crank axle results in the oscillation of a respective, and rotatably connected, driving rod, e.g. 151, which, in turn, causes the oscillation of a respective, and rotatably connected, hydraulic piston rod, which pressurizes hydraulic fluid within the hydraulic cylinders, e.g. 152.
  • the pressurized hydraulic fluid is combined and the combined flow passes through a tube, e.g. 153, to and into a hydraulic accumulator, e.g. 145A.
  • Pressurized hydraulic fluid from the accumulator drives a turbine, e.g. 145B, which in turn spins the rotor of a generator 145C, thereby generating electrical power.
  • the hydraulic fluid After the hydraulic fluid has imparted its energy to the turbine, it is collected and thereafter flows back to the pistons, e.g. 152, through tubes, e.g. 154.
  • the shortening of those portions, e.g. 133, of the cables that connect the buoy to the inertial mass causes the rollers of the traction winches to turn in the reverse direction (to the direction turned when generating maximal power), and that reversed roller rotation causes the crankshafts to also turn in the opposite direction, thereby causing the hydraulic cylinders to be pumped regardless of the direction of the movement of the cables, and the rotational directions of the traction-winch rollers.
  • the shortening of those portions, e.g. 133, of the cables that connect the buoy to the inertial mass likewise cause the rollers of the traction winches to turn in the reverse direction (to the direction turned when generating maximal power).
  • crankshafts are connected to their respective traction winch rollers by means of one-way clutches (or their functional equivalents). This allows the traction-winch rollers to spin in their reverse directions without engaging their respective crankshafts, and without causing the hydraulic cylinders to be pumped.
  • FIG. 24 is a close-up top-down view of one of the pulley, traction winch, and PTO assemblies that characterizes the embodiments illustrated and discussed in relation to FIGs. 22 and 23. All of the specified and/or labelled components are the same as those already discussed in relation to FIGs. 22 and 23.
  • FIG. 25 shows a close-up side view of one of the pulley, traction winch, and PTO assemblies that characterizes the embodiments illustrated and discussed in relation to FIGs. 22 and 23. Many of the specified and/or labelled components are the same as those already discussed in relation to FIGs. 22 and 23.
  • the hollow connecting arm 143 on which the directional rectifying pulley 138 is mounted and from the arms, e.g. 157, of which it is suspended.
  • the pulley and its hollow connecting arm rotate within bearing 144 so that the pulley's plane of rotation encompasses the cable 133.
  • the cable 133 enters the hollow shaft of the hollow connecting arm 143 at its outer end 155. And, the cable exits the hollow shaft of the hollow connecting arm 143 at its inner end 156.
  • the directionally rectified cable 139 travels on to the rollers 140-141 of the traction winch in a plane normal to the axes of rotation of those rollers.
  • FIG. 26 shows a close-up side view of one of the pulley, traction winch, and PTO assemblies that characterizes the embodiments illustrated and discussed in relation to FIGs. 22 and 23. This figure illustrates the opposite side to the side illustrated in Figure 25. Many of the specified and/or labelled components are the same as those already discussed in relation to FIGs. 22, 23, and 25.
  • each crank axle e.g. 158
  • the rotation of each crank axle, e.g. 158 causes a respective and rotatably connected driving rod, e.g. 159, to oscillate back-and-forth.
  • the oscillations of the driving rods, e.g. 159 cause the respective and rotatably connected piston rods, e.g. 160, to oscillate back-and-forth thereby driving the piston head back and forth within the respective hydraulic cylinder, e.g. 152B.
  • Hydraulic fluid pressurized through the oscillations of the piston heads is pooled and fed into a hydraulic accumulator 145A.
  • the pressure- stabilize hydraulic fluid in the accumulator 145A drives a turbine 145B, which, in turn, drives a generator 145C, thereby producing electrical power.
  • FIG. 27 shows a top-down view of an embodiment 130 similar to the embodiment illustrated and discussed in relation to FIGs. 23-26. However, whereas the embodiment illustrated in FIG. 26 incorporated and associated a separate hydraulic PTO with each traction winch, the embodiment illustrated in FIG. 27 pools the pressurized hydraulic fluid generated by all of the hydraulic pistons and feeds the combined stream of pressurized fluid into a single, common, shared hydraulic tube 153, and therethrough into a single, common, shared hydraulic accumulator 162.
  • Pressurized hydraulic fluid from the single accumulator 162 is fed through a tube 163 into a turbine 164 thereby spinning the turbine and the rotatably connected electrical generator 165.
  • the depressurized hydraulic fluid collected within the turbine 164 is passed through a tube 166 into a reservoir 167 and from there back to the hydraulic pistons through a common interconnected hydraulic tube 154.
  • FIG. 28 shows a top-down view of an embodiment 130 similar to the embodiments illustrated and discussed in relation to FIGs. 23-27.
  • the embodiments illustrated in FIGs. 26 and 27 incorporated and utilized hydraulic PTOs
  • the embodiment illustrated in FIG. 28 couples each traction winch, e.g. 161, to a gearbox 168 (by a shaft, e.g. 169).
  • the gearbox is then rotatably connected to an electrical generator 170 (by a shaft, e.g. 171).
  • FIG. 29 shows a perspective view of an embodiment of the present disclosure.
  • a buoyant flotation structure, or buoy, 210 is connected to a submerged inertial mass 214 by two ribbon cables 215 and 216.
  • the ribbon cables come together at a "ribbon junction bar" 217 that is connected by an array 219 of cables that are joined to a connector 218 on and/or in the wall of the inertial mass 214.
  • the ribbon cables 215 and 216 are connected to the buoy by a respective pair of rollers (not visible) over and around which they travel. Each roller is positioned inside a recessed space, e.g. 231, in the side of the buoy.
  • One opposing pair of sides, e.g. 212, of the buoy are approximately flat and vertical.
  • the other sides, e.g. 213, of the buoy are curved and vertical sections through the buoy across section planes approximately parallel to the flat vertical sides, and approximately normal to the resting surface 211 of the body of water on which the buoy floats, have shapes that are approximately hemi-circular.
  • this buoy is able to roll about a horizontal axis that is approximately normal to the faces of its flat vertical sides with relative ease, making it a form of direction rectifying flotation module. While it is not able to easily roll about an axis of rotation that is horizontal and normal to the faces of the flat vertical sides, e.g. 212.
  • the buoy 210 rolls, with relative ease, so as to keep the inertial mass' center of gravity within a plane parallel to its vertical side faces and passing through the buoy's center of mass. However, when the inertial mass moves out of that plane, i.e. toward the flat sides of the buoy, then the angles at which the ribbon cables pass onto each respective roller will change.
  • each ribbon cable Since the longevity of each ribbon cable is not significantly (if at all) affected by the angle at which it travels onto or off of its respective roller, so long as it does so such that its plane of symmetry (normal to its broad surface, and inclusive of its longitudinal axis) is normal to the roller' s axis of rotation, the ability of the buoy to rotate in order to preserve that relationship of each ribbon cable's plane of symmetry to its respective roller's axis of rotation, promotes, and will tend to increase, the longevity of each ribbon cable.
  • each ribbon cable On the end of each ribbon cable, opposite the end connected to the inertial mass 214, is a restoring weight 222 and 223, which provides sufficient downward gravitational force on each weight's respective end of its respective ribbon cable to remove any slack from the respective portion of the respective cable that is connected to the inertial mass 214.
  • the ribbon cables 215 and 216 become tight, and turn their respective rollers as those ribbon cables lengthen, as the inertial mass resists the upward acceleration of the buoy 210.
  • FIG. 29 incorporates a mechanism for adjusting the effective wet weight of the inertial mass 214.
  • Two segments of chain 224 and 225 are connected to a connector 226 on the bottom of the inertial mass 214.
  • the amount of the weight of those chain segments is partially supported by cables 227 and 228, respectively. Winches at the upper end of each "supplemental weight cable" 227 and 228 can adjust the lengths of those cables.
  • the cables are shortened, the ends of the chains distal to the inertial mass are raised, causing more of the weight of the chains to be supported by the buoy, and less of that weight to be supported by, and/or added to, the inertial mass.
  • each "supplemental weight cable" 227 and 228 lengthen those cables, then the ends of the chains distal to the inertial mass are lowered, thereby transferring a greater portion of their weight to the inertial mass.
  • the effective wet weight of the inertial mass 214 can be increased or decreased. It tends to be advantageous to increase the wet weight of the inertial mass when the period or the amplitude of the waves buffeting the buoy increase. Likewise, it is advantageous to decrease the wet weight of the inertial mass when the period or the amplitude of the waves buffeting the buoy decrease.
  • the wet weight of the inertial mass may be "tuned” so as to optimize and/or maximize the amount of electrical power that may be generated with respect to any particular wave climate.
  • Any linked set of weights may be used instead of the chains illustrated in FIG.
  • FIG. 30 shows a top-down perspective of the same embodiment illustrated in FIG. 29.
  • the buoy 210 floats above the submerged inertial mass 214. Dashed outlines indicate the relative positions of the rollers 232 and 233 that are connected at the bottom of the buoy, and typically remain submerged. Winches 229 and 230 adjust the lengths of their respective supplemental weight cables (whose positions are shown by the circular outlines 227 and 228 though not normally visible from this perspective).
  • FIG. 31 shows a sectional view of the embodiments illustrated in FIGs. 29 and
  • the buoy 212-213 is hollow, and defined by walls, e.g. 234, and voids, e.g. 235.
  • the rollers 232 and 233 are positioned in the water outside the buoy, and are connected to the buoy's interior by shafts (not shown) that penetrate the buoy's walls.
  • a respective and connected crankshaft turns a respective set of driving and piston rods, housed in enclosures, e.g. 239.
  • the rods in turn drive hydraulic pistons and pressurize hydraulic fluid that is directed into a turbine 241 which energizes an electrical generator 242.
  • One of the embodiment's two supplemental weights is visible within the section and is illustrated in FIG. 31.
  • the deepest part of the chain (at 228) divides the chain, with the weight of the portion 226 of the chain adjacent to the inertial mass 214 acting to increase the effective wet weight of the inertial mass.
  • the weight of the portion 225 of the chain on the opposite side of 228 being supported by the supplemental weight cable 228 and the buoy to which it is connected (via winch 230).
  • Inertial mass 214 is a hollow vessel containing a void 236 that is nominally filled with water.
  • FIG. 32 shows a side perspective of the embodiment illustrated in FIGs. 29-31.
  • the rollers, e.g. 232, rotate about, and are connected to the buoy, by shafts, e.g. 243.
  • the rollers are positioned within recessed "cut outs," e.g. 231, in the buoy 210.
  • the other components illustrated in FIG. 32 have been discussed in FIGs. 29-31.
  • FIG. 33 shows a side view of an embodiment of the current disclosure.
  • a buoy 100, floating platform, buoyant structure, buoyant chamber, and/or vessel floats adjacent to the surface 101 of a body of water. When the water level rises, as in response to an approaching wave crest, then the buoy moves 107 up.
  • an inertial mass 103, and/or reaction mass preferably positioned at a depth that places it below the wave base 104, resists the buoy's upward acceleration, creating a tension or downward pull 108 in a flexible connector 102 and/or cable that connects the inertial mass 103 to a rotatable pulley 106, gear, roller, drum, rotatable capstan, traction winch, or other rotatable mechanism, journaled, mounted on, and/or attached to, the buoy 100.
  • this wave-energy converter - as illustrated - suffers the disadvantage that when the buoy moves laterally, as in response to the surge component of wave motion, then unless the orientation of that lateral movement is confined to, and/or parallel with, the same plane through which the pulley rotates (i.e. the plane of the page and a vertical plane normal to the pulley's axis of rotation) then the cable will be pulled out of, and/or away from, the groove and/or other alignment feature within the pulley.
  • This misalignment of the cable's pulling with the rotation and/or groove of the pulley can damage the cable and/or significantly reduce its lifetime.
  • the present disclosure includes embodiments utilizing "direction rectifying pulleys" as well as embodiments utilizing "direction rectifying flotation modules and/or hulls.”
  • the pulley 106 has a "plane of rotation" which is the plane containing curved arrow 109. Damage to the pulley and its respective cable are minimized when the cable 102 is pulled in a direction that places it within the pulley's plane of rotation. When a lateral movement of the buoy, causes the cable 102 to be pulled such that its alignment is not within the pulley's 106 plane of rotation, then both the pulley and the cable may be damaged and/or be prematurely worn.
  • FIG. 34 illustrates a basic embodiment of the wave energy device herein disclosed.
  • a positively buoyant structure and/or buoy 100 floats adjacent to a surface 101 of a body of water.
  • the buoy includes a mechanism 106 for generating useful energy (e.g. electrical) or work. That power-generation mechanism 106 obtains its power, and/or is driven or energized by the torque imparted to a pulley 104, roller, gear, wheel, capstan, or other rotatable mechanical interface, by the downward force imparted to a ribbon cable 103 by a negatively-buoyant structure 102, vessel, body, element, object, and/or mass, of relatively great inertia.
  • the ribbon cable in this case, is connected to the inertial mass 102 by means of a "ribbon junction bar" 108 and a single connecting cable 107, although another embodiment has a ribbon cable connected directly to the inertial mass.
  • the inertia of the inertial mass 102 inhibits the buoy's upward acceleration through its creation of a forceful tension in and/or through the ribbon cable 103. That tension is imparted to pulley 104 as a torque. And, that torque is used to directly or indirectly drive an electrical generator (or a generator of another useful energy, product, or result). As the pulley 104 rotates under the torque, the length of the ribbon cable 103 increases.
  • ribbon cable 103 When the buoy 100 falls following the passage of a wave crest, and the approach of a wave trough, ribbon cable 103 will tend to become slack (especially as the inertial mass will typically be rising in response to the upward force imparted to it by the buoy 100 through the ribbon cable 103).
  • An embodiment may utilize a motor (perhaps the same motor/generator used to generate electrical power during the buoy's rise) to rewind the ribbon cable back on to the roller 104 to which one end of the ribbon cable may be attached.
  • an embodiment may utilize a restoring weight attached to the other end 109 of the ribbon cable, and allow the gravitational potential energy of that restoring weight (which would have been lifted when the ribbon cable 103 was paid out during the buoy's rise and the inertial mass' resistance to that motion) to remove the slack in the ribbon cable 103, and to shorten the portion of it intermediate between the buoy and the inertial mass.
  • An embodiment might utilize a hollow, water-filled inertial vessel to provide the needed inertia. It might incorporate and/or enclose added weights within such an inertial vessel in order to provide it with the appropriate degree of negative buoyancy. In one embodiment, rocks are placed inside the inertial mass to increase its net weight.
  • Another embodiment might utilize a solid inertial mass.
  • a solid inertial mass might be composed of a mixture of (typically positively buoyant) recycled plastics and (typically negatively-buoyant) recycled metals.
  • FIG. 35 shows a cross-sectional view of an embodiment that is representative of a set of features disclosed herein that are particularly advantageous.
  • a buoy 900 has a hemi- spherical hull 902 and as a result tends to rotate easily away from its nominally vertical longitudinal axis so as to keep that longitudinal axis (i.e., an axis normal to its upper deck, and about which the buoy has approximate radial symmetry) passing through the approximate center(s) of gravity of the connected set of inertial masses, e.g. 903. And, wherein, the buoy's tendency to keep its own longitudinal vertical axis coaxial with a longitudinal axis of the entire embodiment will tend to minimize, if not avoid, the kind of wear and damage to the ribbon cable 904 that tends to result from the
  • Rotatably connected to buoy 900 is a roller 905 that is positioned in the water and outside of the buoy's interior. This placement of the roller, and the ribbon cable rotatably connected to it, in a condition of constant submersion facilitates the reduction and/or prevention of corrosion on and/or within those components.
  • One end of the ribbon cable 904 is connected, via a ribbon junction bar 908, to a set of interconnected inertial masses, e.g. 903.
  • the other end of the ribbon cable 904 i.e. the end of the portion of the ribbon cable that is on the other side of the roller 905 is connected, via another ribbon junction bar 909, to a set of interconnected restoring weights, e.g. 907.
  • An embodiment of the present disclosure may have any number of inertial masses. It may have any number of restoring weights (or none at all). It may utilize one or more cables and/or one or more multi-stranded ribbon cables. One end of its cables or ribbon cables may be attached to one or more rollers and those cables or ribbon cables may be "rewound" in order to remove slack from the cable during the buoy's descent by a motor, e.g. electrical or hydraulic. One end of its cables or ribbon cables may be attached to one or more restoring weights, the gravitational potential energy of which will cause slack to be removed from the cables or ribbon cables.
  • the buoys may be of any shape, geometry, design, and may be fashioned of any material or combination of materials, and be fabricated by any method, process, or device.
  • the cables or ribbon cables may be made of any material, natural or synthetic, and be of any diameter, width, thickness, etc.
  • the pulleys, rollers, gears, etc. may be of any number and diameter.
  • the transmission of energy from the rollers, pulleys, gears, etc., to the generator may be by a simple direct-drive shaft, a gear box, a hydraulic fluid circuit, or any other mechanism, technology, or manner, an embodiment may utilize any number of electrical generators, or none at all (e.g. if it uses the energy extracted from the waves to desalinate water through water pressure, or if it
  • FIG. 36 shows a top-down view of an embodiment of the current disclosure.
  • Flotation module 200 is shown to contain two apertures 202 and 203 which vertically pass through the entire structure of flotation module 200.
  • Pulleys/capstans/sheaves (“drums”) 206-210 can be arrayed linearly as shown, with flexible connector 204 passing alternatively above and below adjacent drums in a serpentine manner (detailed further in FIG 37).
  • Flexible connector 204 is a linear array of individual cables/wires/chains/etc. ("strands") arranged in a ribbon shape. This arrangement allows a relatively large tensile member to pass over a relatively small radius without causing damage to or rapidly fatiguing the tensile members' structures.
  • Power-take-off (“PTO”) modules 211 and 212 are attached to the central shafts of one or more of the drums 206-210 (in this example, both sides of drum 208). PTO modules 211 and 212 can consist of a generator, gearbox, hydraulic pump, or any number or combination of other power transfer mechanisms.
  • FIG. 37 shows section cut 2-2 from FIG 36.
  • a vertical cross section through flotation module 200 is shown in this figure. It can be seen to be floating in body of water 201. Apertures 202 and 203 are shown to vertically pass though the structure of flotation module 200. Drums 206-210 are shown in their linear array with flexible connector 204 passing in a serpentine manner around drums 206-210. PTO module 211 is shown to be connected to drum 208 and five drums are shown to be used, however more or fewer drums and/or PTO modules could be utilized. One end of flexible connector 214 (all strands comprising the ribbon shape of flexible connector 214) is attached to ribbon junction bar 218.
  • Mating flexible connector 219 depends from ribbon junction bar 218 and may be comprised of a single flexible connector (rope, chain, wire, etc.) or a plurality. Restoring weight 220 is shown to be attached to mating flexible connector 219. The other end of flexible connector 213 also is shown to attach to a ribbon junction bar 215 in a similar manner as the side possessing the restoring weight.
  • One or more mating flexible connectors depend from ribbon junction bar 215 and mate to inertial mass (“IM") 217.
  • IM 217 may consist of a structure containing water filled voids, which overall has a net weight that is positive in water. Relative motion causing increasing separation between the IM 217 and the floatation module 200 will cause drums 206-210 to rotate (221, 222).
  • Flexible connector 204 does not slip relative to the surface of drums 206-210 because the serpentine arrangement of the flexible connector 204 through the drums multiplies the tension provided from the restoring weight 220 to provide sufficient friction between the drums 20-6-210 and flexible connector 204.
  • connector/drum arrangement is commonly exploited in traction winches.
  • FIG. 38 shows a top-down view of an embodiment of the current disclosure.
  • Floatation module 750 is shown to contain a single aperture 752
  • Flexible connector 753 is shown to be of a ribbon- shaped configuration where its sub-elements are arranged side by side.
  • the individual strands of the ribbon-shaped flexible connector 753 can be cables, chains, wire, rope, or a multitude of other linear tensile members.
  • Flexible connector 753 is shown to pass up and over track assembly 755 and between track assemblies 754 and 756. These track assemblies will be detailed and described in the following figure.
  • FIG. 39 shows vertical cross section 37-37.
  • Flotation module 750 is shown in cross section floating on body of water 751 and through body aperture 752 is clearly visible.
  • Inertial mass (“IM") 759 is shown with connecting element 760 mating it to ribbon junction bar 761.
  • Individual strands 753D of ribbon-shaped flexible connector 753 are shown to terminate on the ribbon junction bar 761.
  • Flexible connector 753 A is shown passing up and over track assembly 755 and between track assemblies 754 and 756.
  • Track assembly pairs 754/755 and 755/756 form two linear cable engines. These linear cable engines exert a compressive force on flexible connector 753.
  • As flotation module 750 moves away from IM 759 due to wave action present in body of water 751, flexible connector 753 is pulled through both linear cable engines 754/755 and 755/756.
  • FIG. 40 shows a graph in which the line 200 illustrates the changes in the average separation distance between the flotation module (i.e., buoy) and the inertial mass of an embodiment (i.e., device) of the present disclosure that might be manifested by the device as the time average amount of upward force, and/or the average impulse, being imparted to the inertial mass by the buoy through the flexible connector connecting the two is altered through an alteration of the resistive torque applied to the pulley(s) over which the flexible connector travels.
  • the line 200 illustrates the changes in the average separation distance between the flotation module (i.e., buoy) and the inertial mass of an embodiment (i.e., device) of the present disclosure that might be manifested by the device as the time average amount of upward force, and/or the average impulse, being imparted to the inertial mass by the buoy through the flexible connector connecting the two is altered through an alteration of the resistive torque applied to the pulley(s) over which the flexible connector travels.
  • the average separation distance between the buoy and the inertial mass is about 50 meters. This is the "average" separation distance, and the instantaneous separation distance between the buoy and the inertial mass may be oscillating with a relatively large range of distances (which oscillation can have an amplitude roughly corresponding to an amplitude of the waves).
  • the average impulse imparted to the inertial mass by the buoy is increased to an amount (i.e., average_impulse_202) that is greater than average_impulse_200, then the average separation distance begins to decrease, and the inertial mass begins to move closer and closer to the buoy from which it is suspended.
  • This increased impulse can be created by increasing an average countertorque applied by the power-take-off system.
  • the average impulse imparted to the inertial mass by the buoy is decreased to an amount (i.e., average_impulse_204) that is less than
  • the average separation distance begins to increase, and the inertial mass begins to move further and further away from the buoy, i.e. its average depth increases over time.
  • the new stable average separation distance is now at about 62 meters, i.e. it is stable but it is greater than the average separation distance that characterized the original stable separation distance of 50 meters.
  • FIGs. 41-44 show four flow-charts (subfigures A through D respectively). Each of the four flow-charts depicts a control system circuit, or a part of a control system circuit, that can be incorporated within an embodiment of the present disclosure.
  • An embodiment of the present disclosure can have zero, one, or more than one of the disclosed circuits.
  • An embodiment of the present disclosure can have a control system circuit that includes, but does not consist only of, one of the depicted circuits.
  • These control system circuits can be implemented in hardware (e.g. as a programmed chip or circuit board), in software (e.g. as a program or driver), or in a combination or hybrid of the two.
  • a main purpose of the control system circuits depicted is to regulate the depth of the inertial mass so that in normal operation it does not sink to waters that are too deep (e.g. causing a flexible connector to experience a snap load) and so that in normal operation it does not rise to waters that are too shallow (e.g. so that it does not impact the bottom surface of the flotation module). This can be accomplished by varying the amount of resistance, countertorque, or stopping power applied to the powertrain (e.g. the pulley/capstan or shaft) when the flotation module is moving up and down due to waves.
  • the powertrain e.g. the pulley/capstan or shaft
  • the inertial mass typically experiences a downward gravitational force due to the net weight of the "inertial mass weighted portion,” (the portion of the inertial mass that has a positive net weight, whether integral with the inertial mass or depending from it) tending to cause it to sink.
  • the average and/or cumulative balance, ratio, or equilibrium between this net downward gravitational force and any upward buoyant force transmitted to the inertial mass via the depending connector determines, in part, the depth of the inertial mass (and/or its distance from the flotation module).
  • the more countertorque is applied by the powertrain the more buoyant upward forces experienced by the flotation module will be transmitted through the depending connector to the inertial mass, entailing that the inertial mass will experience relatively greater upward forces when the flotation module accelerates upward, offsetting the downward gravitational force experienced by the inertial mass.
  • the less countertorque is applied by the powertrain the less that buoyant upward forces experienced by the flotation module will be transmitted through the depending connector to the inertial mass, entailing that the inertial mass will experience relatively lesser upward forces when the flotation module accelerates upward.
  • the greater the amount of ambient available wave energy e.g. the greater the average wave height holding period constant, or the shorter the wave period holding wave height constant
  • FIGs. 41 to 44 depicts a control system in which at least two sensors 22-1000 and 22-1010 record information from the environment. At least one of these at least two sensors is a sensor for an indicator of wave energy 22-1000. At least one of these at least two sensors is a sensor for an indicator of inertial mass depth 22- 1010.
  • a sensor for an indicator of wave energy 22-1000 records, receives, or senses a physical characteristic and/or signal relevant to the computation of an indicator, predictor, correlate, measure, estimate, and/or statistic of the ambient available wave energy.
  • a sensor for an indicator of wave energy 22-1000 can be a camera located on the side of the flotation module, having a lens directed laterally toward the horizon, so as to provide video data relevant to estimating the current wave height and period.
  • a sensor for an indicator of wave energy 22-1000 can be an accelerometer in the flotation module that records data pertaining to the velocity and acceleration of the flotation module, data that is relevant to calculating an estimate of the occurrent wave height and period and thus the ambient available wave energy.
  • a sensor for an indicator of wave energy 22-1000 can be a radio or satellite receiver that can receive weather data transmitted from a weather station pertaining to the wave height and period in the geographic area where the converter is located, information that is relevant to calculating an estimate of the ambient available wave energy.
  • a sensor for an indicator of wave energy 22-1000 can be an electrical circuit that senses and records the amount of electrical power the converter is currently generating, data that is relevant to calculating an estimate of the ambient available wave energy.
  • a sensor for an indicator of wave energy 22-1000 can be a rotary encoder operatively connected to a generator shaft so as to record the angular velocity of said shaft, data that is relevant to calculating an estimate of the ambient available wave energy.
  • a sensor for an indicator of inertial mass depth 22-1010 records, receives, or senses a physical characteristic and/or signal relevant to the computation of an indicator, predictor, measure, estimate, correlate, and/or statistic of the depth in the body of water of the inertial mass, and/or an indicator, predictor, measure, estimate, correlate, and/or statistic of the vertical separation distance between the inertial mass and the flotation module.
  • a sensor for an indicator of inertial mass depth 22-1010 can be a sonar sensor located on a bottom portion of the flotation module that emits a sonar signal toward the inertial mass to measure the distance between the flotation module and the inertial mass.
  • a sensor for an indicator of inertial mass depth 22-1010 can be a rotary encoder operatively connected to a capstan/pulley or shaft thereof at the flotation module. By measuring the angular velocity of said shaft, such an encoder can provide data relevant to measuring the cumulative angular displacement of the pulley/capstan and/or the cumulative translation of a depending connector operatively connected thereto. This data is relevant to calculating an estimate of the depth in the body of water of the inertial mass and/or the distance between the inertial mass and the flotation module.
  • a sensor for an indicator of inertial mass depth 22-1010 can be an audio receiver at the flotation module that senses and processes "pings" from an audio emitter on the inertial mass.
  • the latency of such an audio signal can be used to estimate the distance between the inertial mass and the flotation module.
  • a sensor for an indicator of inertial mass depth 22-1010 can be many different types of sensor.
  • the sensor for an indicator of wave energy 22-1000 transmits a digital data packet or an analog signal, or returns a value (e.g. as part of a function call), to an associated processor 22-1001 configured to compute a statistic, feature, measure, predictor, estimate, correlate, function, or indicator of the ambient available wave energy.
  • the sensor for an indicator of inertial mass depth 22-1010 transmits a digital data packet or an analog signal, or returns a value (e.g. as part of a function call), to an associated processor 22-1011 configured to compute a statistic, feature, measure, predictor, correlate, estimate, function, or indicator of the depth in the body of water of the inertial mass (or the separation distance between the inertial mass and the flotation module).
  • Each of processors 22-1001 and 22-1011 transmits a digital data packet or an analog signal, or returns a value (e.g. as part of a function call), to a countertorque processor 22-1020 configured to calculate an appropriate amount of countertorque, resistance, stopping power, or power-take-off to be applied to the rotating shaft and/or to the pulley/capstan.
  • the countertorque processor can compute this value as a function of, or by using as input: (1) the current or recent ambient available wave energy (or a proxy, indicator, or correlate thereof), e.g.
  • the wave energy statistic processor 22-1001 as received as an input data or signal from the wave energy statistic processor 22-1001; and (2) the current or recent depth in the body of water of the inertial mass (or a proxy, indicator, or correlate thereof) or the current or recent separation distance between the flotation module and the inertial mass (or a proxy, indicator, or correlate thereof), e.g. as received as an input data or signal from the inertial mass depth statistic processor 22-1011.
  • Countertorque processor 22-1020 can be a PID control, a neural network, a lookup table, a mathematical function, a statistical or machine learning routine, or any other kind of processor capable of producing a countertorque directive (i.e. an optimal, desired, or appropriate countertorque) in approximately real time given the two inputs outlined in the previous paragraph.
  • Countertorque processor 22-1020 can include a physics simulation engine enabling the control system to benefit from Monte Carlo simulation of various potential countertorque values.
  • Countertorque processor 22-1020 can send a digital data packet or an analog signal, or return a value (e.g. as part of a function call), to one or more components or control systems responsible for effectuating the countertorque directive.
  • the countertorque processor 22- 1020 can send a digital data packet or an analog signal, or return a value (e.g. as part of a function call), to a generator 22-1100 (or to a generator control system).
  • the countertorque processor can send a digital data packet containing a countertorque directive to a generator control system responsible for increasing and decreasing the excitation of generator field coils, enabling the countertorque realized by the generator to be increased and decreased.
  • the countertorque processor can send a digital data packet containing a countertorque directive to a hydraulic valve control system responsible for opening and closing a hydraulic valve, enabling the countertorque realized by the generator to be increased and decreased.
  • the countertorque processor 22- 1020 can send a digital data packet or an analog signal, or return a value (e.g. as part of a function call), to one or more power electronics subsystems or circuits 22-1200.
  • the countertorque processor can send a digital data packet containing a countertorque directive to a control system responsible for controlling a grid-side converter, thereby varying the load experienced by the generator, thereby varying the countertorque it can develop or realize.
  • the countertorque processor 22- 1020 can send a digital data packet or an analog signal, or return a value (e.g. as part of a function call), to a clutch 22-1300 disposed in the power-transmission pathway from the pulley/capstan to the generator (or a control system for said clutch).
  • the countertorque processor can send a digital data packet containing a countertorque directive to a control system responsible for controlling the engagement of the clutch, thereby varying the countertorque or resistance transmitted to the pulley/capstan.
  • the countertorque processor 22- 1020 can send a digital data packet or an analog signal, or return a value (e.g. as part of a function call), to a brake 22-1400 operatively connected to the powertrain (e.g. the pulley/capstan or the shaft) (or to a control system for said brake).
  • the countertorque processor can send a digital data packet containing a countertorque directive to a control system responsible for controlling the engagement of the brake, thereby varying the countertorque or resistance transmitted to the pulley/capstan.
  • the control system depicted in FIGs. 41-44 can be active continuously (e.g. in a looping or repeating fashion); intermittently; in an interrupt-based fashion (e.g. when triggered by specified sensor values, e.g. from sensors 22-1000, 22-1010, and/or other sensors or processors); at regular time steps according to a clock cycle; and/or any combination thereof; and/or on another appropriate cycle or schedule.
  • the countertorque processor 22-1020 receives input from a sensor for an indicator of wave energy 22-1000 but not from a sensor for an indicator of inertial mass depth 22-1010. In another alternate embodiment (not shown), the countertorque processor 22-1020 receives input from a sensor for an indicator of inertial mass depth 22-1010 but not from a sensor for an indicator of wave energy 22-1000.
  • FIGs. 45 to 48 show a temporal progression of side-view cross sections of an embodiment similar to the one shown in FIG. 54.
  • subfigure 45A to subfigure 48T shows the response of the converter as the water level rises, falls, and rises again, relative to the mean water level (dotted line 2-802), during the passage of a wave, e.g. from wave trough to wave trough.
  • subfigures are to be understood as frames of an animation.
  • the subfigures can be understood to "loop" under certain assumptions, i.e. subfigure 48T can be understood to immediately precede subfigure 45 A, e.g., on the assumption that the device is in continual, repeating 2.5 meter waves on a 10 second period.
  • Subfigure 45A shows the converter in a configuration that it can assume when the water level 2A-100 is approximately at a temporal and spatial local minimum, i.e. the trough of a wave.
  • the mean water level i.e. the water level when the body of water is not disturbed by waves
  • Subfigure 47K shows the converter in a configuration it can assume when the water level 2K-100 is approximately at a temporal and spatial local maximum, i.e. the crest of a wave.
  • the mean water level is shown by dotted line 2-802.
  • Subfigures 46F and 48P show the converter in configurations it can assume when the water level (2F-100 and 2P-100 respectively) is approximately at the mean water level. I.e. the water level (2F-100 and 2P-100 respectively) and the mean water level (2-802) coincide. In 46F the water level is rising toward a crest and in 48P it is falling toward a trough.
  • the wave height/wave amplitude shown (vertical distance between the maximal water level 2K-100 and the minimal water level 2A-100) is approximately 2.5 meters and the wave period shown is approximately 10 seconds.
  • this disclosure applies equally to a converter capable of operating in any wave conditions.
  • the slope or curvature of the water's surface is not shown, i.e. the water level is designated by a flat horizontal line.
  • the wavelength of deep-water waves of the size shown can be 200 meters or greater, making the local curvature of the water's surface essentially negligible.
  • horizontal dotted lines 2-800 indicate for reference the position of the top of the restoring weight from subfigure A.
  • Horizontal dotted lines 2-801 indicate for reference the position of the top of the inertial mass from subfigure A.
  • flotation module 2A-105 floats on the surface of the water 2A-100 which is approximately at a local minimum, i.e. the device is in the trough of a passing wave.
  • Inertial mass 2A-140 substantially encloses or "traps" a large volume of water inside a substantially rigid outer shell. It is to be understood that inertial mass 2A-140 has an internal and/or integral inertial mass weighted portion and therefore inertial mass 2A-140 has an average effective density (taking into account both its integral internal mass weighted portion and its enclosed water) similar to the average effective density of the embodiment of Figure 54.
  • Inertial mass 2A-140 is operatively connected to flotation module 2A-105 and restoring weight 2A-160 via depending connector 2A-150.
  • Depending connector 2A-150 is operatively connected to pulley/capstan 2A-125 at the flotation module, and can wind around it several times as in the embodiment of FIG. 54.
  • a generator is operatively connected to pulley/capstan 2A-125.
  • Inertial mass 2A-140 has a downward momentum developed during the converter's earlier descent into the wave trough. This earlier descent corresponds to the dynamics of subfigures 2Q through 2T, where it can be seen that the inertial mass (e.g. 2Q-140) is progressively descending, i.e. has a downward momentum.
  • flotation the module 2B-105 is displacing more water in 45B than in 45A.
  • the flotation module therefore experiences a larger buoyant force than before and can rise.
  • flotation module 2B/H-105 has risen significantly.
  • inertial mass 2B-140 and/or restoring weight 2B- 160 must also rise. Because inertial mass 2B-140 has relatively much larger effective mass (inertia) than does the restoring weight 2B-160, it is easier for restoring weight 2B- 160 to be accelerated up than for inertial mass 2B-140 to be accelerated up.
  • restoring weight 2B-160 can rise, e.g. to and past the position indicated by 2H-160.
  • depending connector 2B-150 can operatively rotate pulley/capstan 2B-125 if there is sufficient friction between the connector and the pulley/capstan.
  • the generator can exert a countertorque and/or resistance to the turning of the pulley/capstan (and must exert such a countertorque, if the device is to generate power), at least some of the buoyant force acting on the flotation module 2B-
  • the inertial mass 2B-140 can be transmitted through the depending connector to the inertial mass 2B-140 (and must be so transmitted, if the device is to generate power). This can cause the inertial mass to accelerate upward, slowing its downward movement (e.g., subfigures 45A, 45B, 45C, 45D) and eventually developing an upward movement (e.g., subfigures 46G, 46H, 461, 46J, etc.). In this way, the movements of the inertial mass will typically be reciprocal but out of phase with the movements of the flotation module. The time period during which the flotation module is rising, accelerating upward, and/or moving away from the inertial mass can be referred to as the "upstroke.”
  • the flotation module After or around the time that the flotation module has reached a crest of a wave (e.g. subfigure 47K), the flotation module begins to move downward under gravity (e.g. subfigures 47K to 48T).
  • the time period during which the flotation module is falling, accelerating downward, and/or moving toward the inertial mass can be referred to as the "downstroke.”
  • the device can and should be configured so that on average the generator resists the turning of the pulley/capstan less than it does on average during the upstroke, allowing the restoring weight to descend more easily relative to the flotation module than it would if the generator were applying and/or providing greater countertorque and/or resistance.
  • the restoring weight When moving downward and/or away from the flotation module, the restoring weight will pull the depending connector after it, thereby
  • FIG. 49 shows a cross sectional view of an embodiment of the current disclosure, namely an embodiment of an inertial wave energy converter of a simple type.
  • Lifting module 571 is buoyant and floats on the surface of a body of water 570.
  • Inertial mass 581 is submerged and suspended beneath the lifting module and can contain and/or at least partially entrap a large mass of water.
  • Restoring weight 578 is submerged and suspended beneath the lifting module and has an average density greater than water, perhaps significantly greater.
  • Power chain 575/576 is connected to inertial mass 581 at attachment point 580 and to restoring weight 578 at attachment point 577, and passes operatively about pulley 573 which is located in/at/atop lifting module 571 and can be operatively connected to a generator.
  • Pulley 573 can be a chainwheel or grip pulley or other pulley adapted to engage with the flexible connector and transmit a force.
  • Inertial mass tether 574 is attached to lifting module 571 at attachment point 572 and to the inertial mass 581 at attachment point 579. [00213]
  • inertial mass 581 can have net weight greater than that of restoring weight 578. In an equilibrium configuration, e.g. when the device is not being perturbed by waves, the tether 574 prevents the inertial mass from descending toward the seafloor.
  • inertial mass 581 When waves perturb the device, an upward acceleration of lifting module 571 and an associated tension in tether 579 can "launch" inertial mass 581 upward. From that point onward, if perturbation by waves is sufficiently vigorous, an active control of the generator's or power-take-off system's degree of resistance and/or the use of a brake (e.g. a disc brake) operationally connected to pulley 573 can keep inertial mass 581 oscillating relative to restoring weight 578 without tether 579 becoming taut, while power is extracted from that oscillation. In such a manner, inertial mass 581 can be “dynamically suspended.”
  • a brake e.g. a disc brake
  • FIG. 50 shows a cross sectional view of an embodiment of the current disclosure, namely an embodiment of an inertial wave energy converter of a simple type.
  • FIG. 51 shows a cross sectional view of an embodiment of the current disclosure, namely an embodiment of an inertial wave energy converter of a simple type.
  • This embodiment is identical to that of Fig.
  • stop 595 is provided, and restoring weight 597 passes coaxially around power chain segment 599/593. I.e. power chain segment 599/593 passes through aperture 598 in restoring weight 597. Stop 595 is fixedly attached to power chain segment 599/593 so that when restoring weight 597 rises, it contacts stop 595 and cannot rise further.
  • inertial mass 601 is suspended and limited from further downward movement.
  • FIG. 52 shows a cross sectional view of an embodiment of the current disclosure, namely an embodiment of an inertial wave energy converter of a simple type.
  • This embodiment is identical to that of Fig. 50 except that in lieu of stop 585, restoring weight 617 is positioned below the inertial mass and its segment 619 of power chain 613/614 passes through a vertical aperture 616 in the inertial mass. Consequently, when the inertial mass falls relative to the restoring weight, and/or the weight rises relative to the inertial mass, the two bodies come into contact and they are
  • FIG. 53 shows a cross sectional view of an embodiment of the current disclosure, namely an embodiment of an inertial wave energy converter of a simple type.
  • This embodiment is identical to that of Fig. 49 except that in this embodiment tether 846 restrains the downward movement of inertial mass 847, rather than tether 574. Tether 846 connects the inertial mass 847 to the restoring weight 845. When the inertial mass falls, tether 846 becomes taut and no further downward movement of the inertial mass is possible.
  • FIG. 54 shows a perspective view of an embodiment of the current disclosure.
  • Converter 1-104 floats at, upon, and/or adjacent to a surface 1-100 of a body of water having waves.
  • the converter includes a flotation module 1-105, an inertial mass 1-140, a restoring weight 1-160, and a depending connector 1-150.
  • the inertial mass 1-140 and the restoring weight 1-160 depend from the flotation module 1-105 by the depending connector 1-150 and are suspended thereby in the body of water, i.e. beneath a surface 1- 100 of the body of water.
  • Inertial mass 1-140 and restoring weight 1-160 are fully submerged.
  • Flotation module 1-105 is buoyantly at the surface, i.e. is partly below and partly above a surface of the body of water. The figure shows both above-surface and below- surface components of the converter, as do most perspective views in this disclosure.
  • Inertial mass 1-140 is substantially spherical and has a hollow, approximately spherical interior void containing and/or at least partially enclosing or confining a significant volume of seawater.
  • inertial mass 1-140 can have a radius of approximately 10 meters and a hollow interior volume of approximately 4000 cubic meters.
  • inertial masses similar to 1-140
  • inertial mass that are characterized by, and/or possess, other shapes, and are substantially non- spherical.
  • One other embodiment includes an inertial mass that is substantially cylindrical.
  • the scope of the current disclosure includes embodiments possessing inertial masses of any shape, as well as including multiple linked inertial masses.
  • the walls of inertial mass 1-140 almost entirely enclose an approximately spherical volume of water 1-141.
  • the walls of inertial mass 1- 140 are thin, largely rigid, and largely impermeable.
  • inertial mass 1-140 can be made of plastic, aluminum, steel, or any other material having the appropriate rigidity and impermeability.
  • Inertial mass 1-140 can form a rigid "shell” substantially enclosing a large mass of water 1-141.
  • the mass of such enclosed water can be "added to" the mass of inertial mass 1-140 for the purposes of deriving inertia under acceleration, allowing one to speak of the inertial mass's "effective mass” and "effective inertia,” i.e. its mass and inertia taking into account all, or any portion of, the mass of the water effectively confined or trapped within it.
  • inertial mass can refer to an inertial mass taking into account any enclosed and/or confined water, or it can refer to an inertial mass without taking into account any enclosed and/or confined water.
  • the phrase "the mass of inertial mass X" can refer to the mass of inertial mass X excluding the mass of any water enclosed and/or contained in inertial mass X, or it can refer to the mass of inertial mass X including the mass of any water enclosed and/or contained in inertial mass X (i.e., its "effective mass").
  • the phrase “the mass of inertial mass X” can refer to the mass of inertial mass X excluding the mass of any water enclosed and/or contained in inertial mass X, or it can refer to the mass of inertial mass X including the mass of any water enclosed and/or contained inertial mass X (i.e., its "effective mass”).
  • An aperture or opening 1-141 at a top portion of inertial mass 1-140 can allow depending connector 1-150 to pass through a top portion of the inertial mass.
  • Depending connector 1-150 makes a connection to the inertial mass at a lower interior portion thereof, e.g. 1-151.
  • the depending connector can connect to the inertial mass near a center of mass or a center of volume of the inertial mass, or at other sites on the inertial mass that analysis may show to be advantageous.
  • Inertial mass 1-140 has, contains, and/or is connected to an inertial mass weighted portion 1-145.
  • the purpose of the inertial mass weighted portion 1-145 is to provide the inertial mass with sufficiently positive net weight, i.e. sufficiently negative buoyancy, so as to cause it to accelerate at least somewhat rapidly downward under gravity after being lifted, raised, and/or drawn upward.
  • An inertial mass weighted portion can be the walls of the inertial mass, in which case such walls can be relatively thick and/or massive.
  • an inertial mass weighted portion can be a discrete weight depending from the inertial mass, e.g. by a flexible connector.
  • the inertial mass weighted portion 1-145 can be a quasi-discrete weight integrated into and/or embedded within the inertial mass and/or rigidly attached thereto, e.g. at a bottom portion of the inertial mass.
  • Other similar means of providing an inertial mass weighted portion are also covered by this disclosure.
  • the inertial mass weighted portion can be made of concrete, iron, steel, lead, or any other material or combination of materials having an average density greater than water and a sufficiently low specific cost.
  • inertial mass weighted portion 1-145 can have a density of 2400 kilograms per cubic meter and a mass of 180,000 kilograms.
  • Flotation module 1-105 floats at a surface 1-100 of the body of water and has a waterline 1-110 whose vertical position 1-110 on flotation module 1-105 can change at least transiently.
  • the vertical position of waterline 1-110 on the flotation module 1-105 might at least transiently rise or fall due to the passing of waves, or due to a change in a downward force on the flotation module, at least until an equilibrium water line is re-established.
  • Flotation module 1-105 is buoyant and is preferably broad and "flat,” allowing it to experience a relatively large increase in buoyant force in response to a relatively small change in displacement, i.e. in response to a relatively small change in the average vertical position of its waterline 1-110.
  • flotation module 1-105 can have a height of 2 meters and can have a square horizontal cross section having lateral side lengths of 15 meters.
  • Flotation module 1-105 can have an average density of 150 kilograms per cubic meter.
  • Flotation module 1-105 has a central void or aperture 1-115 communicating between its top and bottom portions.
  • a top portion of flotation module 1-105 bears and/or supports a power-take-off assembly including a bearing-and-generator housing 1- 120, a bearing housing 1-121, a shaft 1-122, and a pulley/capstan 1-125.
  • Bearing-and- generator housing 1-120 and bearing housing 1-121 straddle central aperture 1-115, and each contains a bearing assembly allowing shaft 1-122 to be rotatably supported above central aperture 1-115.
  • Pulley/capstan 1-125 is operatively connected to shaft 1-122 so that the rotation of pulley/capstan 1-125 about a horizontal, longitudinal axis thereof is associated with shaft 1-122 rotating about the same axis.
  • Bearing-and-generator housing 1-120 contains an electrical generator operatively connected to shaft 1-122.
  • a gearbox or other similar mechanism can be provided in the power-transmission pathway from the pulley/capstan to the generator.
  • Bearing-and-generator housing 1-120 can contain a brake, e.g. a disc brake or a magnetic particle brake.
  • the brake can provide the ability to apply a stopping force to the rotation of the shaft 1-122. In different circumstances, it can be useful to use the brake in addition to, or in lieu of, the generator, to apply a stopping force (i.e.
  • the brake's control system can be integrated into or communicate with that of the generator and other power-take-off components. By using both the brake and the generator, a control system having at its disposal both a brake and a generator can transmit to the inertial mass greater amounts of buoyant force (i.e.
  • buoyant force acting upon the flotation module than a control system having at its disposal a generator alone.
  • a first end of depending connector 1-150 attaches to inertial mass 1-140 at 1- 151 and ascends through aperture 1-115 and is operatively connected to pulley/capstan 1-125 at 1-152.
  • Depending connector 1-150 can be made of steel cable, metal chain, synthetic rope, or any other flexible material with sufficient tensile strength.
  • Depending connector 1-150 can have rigid segments or sections. For approximate scale (merely illustrative), depending connector 1-150 can have a total length of 200 meters.
  • Depending connector 1-150 can be wound around pulley/capstan 1-125 several times, i.e. its contact with the circumference of the pulley/capstan can define more than 2 times pi radians of arc. Winding the depending connector several times around the
  • pulley/capstan can increase the friction between the depending connector and the pulley/capstan so as to provide more effective transmission of force, e.g. in accordance with the capstan equation.
  • Another end and/or part of depending connector 1-150 can then descend through aperture 1-115 and be connected at 1-161 to restoring weight 1- 160.
  • One end of depending connector 1-150 is connected to inertial mass 1-140 and the other end is connected to restoring weight 1-160.
  • An intermediate portion of depending connector 1-150 is operatively connected to pulley/capstan 1-125, e.g. by several windings therearound.
  • Restoring weight 1-160 can be negatively buoyant, i.e. can have an average density greater than that of water. It can be made of concrete, steel, iron, lead, stone, or any other material or combination of materials with a favorable specific cost (i.e. cost per unit mass or volume). For approximate scale (merely illustrative), restoring weight 1-160 can have a density of 2,400 kilograms per cubic meter and a mass of 8,000 kilograms.
  • Restoring weight 1-160 can have a small net weight relative to the inertial mass weighted portion 1-145, so that it has only enough net weight to "rewind" the depending connector 1-150, or it can have a "large” net weight approaching or even exceeding that of the inertial mass weighted portion 1-145, so that it stores appreciable gravitational potential energy when lifted which can be “recaptured” as it descends by a bi-directional power- take-off system. [00237] Note that "net weight” means gravitational weight net of buoyant force.
  • Pulley/capstan 1-125 can have a spiral groove or grooves around its exterior, and/or other circumferential guiding projections, disposed and/or used so as to guide and constrain the winding of depending connector 1-150.
  • a single long spiral groove is shown running from one end of the pulley/capstan (near 1-120) to the other (near 1-121).
  • pulley/capstan 1-125 rotates, the winding therearound of depending connector 1-150 is guided and limited by the spiral groove, so that adjacent winds of the depending connector do not touch each other. This has the advantage of reducing the likelihood of tangling and diving and potentially lengthening the life of the depending connector.
  • the relative height of the groove walls disposed along the length of the pulley/capstan might diminish toward either end of the pulley/capstan. This might allow the connector 1-150 to slip across groove walls if the extent of the connector's movement would otherwise tend to drive it one or the other end of the pulley/capstan and thereafter create a blockage (i.e. in which the connector could not move any further away from the pulley/capstan's center).
  • the power-take-off assembly can be configured with a control system and/or a passive or active clutch so that the degree of countertorque (i.e. resistance to shaft rotation, i.e. stopping force) applied to the shaft by the generator or power-take-off assembly can be different at different times.
  • the power-take-off system can be configured to provide a countertorque whose magnitude is approximately proportional to the speed of shaft rotation (or the absolute value thereof). And/or, the power-take-off system can be configured to provide a countertorque whose magnitude is approximately proportional to the square of the speed of shaft rotation. And/or, the power-take-off system can be configured to provide zero countertorque when the distance between the inertial mass and flotation module is decreasing and a nonzero countertorque when the distance between the inertial mass and flotation module is increasing. And so on.
  • a wide variety of control strategies is possible. And, any or all of such strategies can be implemented, within the power-take-off system of the same embodiment, in response to the detection of specific wave conditions, atmospheric conditions, farm electrical-grid conditions, etc.
  • Countertorque can be controlled using differential excitement of field coils in the generator, i.e. a circuit that sets the degree of electrical excitement in said field coils at different levels at different times, subject to a control system. And/or, countertorque can be controlled by varying the load felt by the generator, e.g. by providing power electronics and a circuit implementing field-oriented control or direct torque control in the circuit of which the generator is a part. And/or, countertorque can be controlled by providing an electromagnetic and/or mechanical clutch that transmits different amounts of shaft 1-122's torque to the generator at different times, subject to a control system. Other means of providing controllable/variable countertorque are possible.
  • the water level adjacent to converter will periodically be at local minimum, i.e. the flotation module will periodically be in the trough of a passing wave.
  • the water level begins to rise, e.g. due to the receding of the wave trough and/or the approach of a wave crest, the waterline 1-110 on the flotation module can rise, the displacement of the flotation module can increase, and the buoyant force acting on the flotation module can increase. This can cause the flotation module to accelerate upward and/or rise.
  • the inertial mass 1-140 which is operatively connected to the flotation module by the depending connector 1-150, has significant effective inertia and will resist being accelerated upward by a force transmitted to it via the depending connector.
  • the inertial mass 1-140's resistance to rising can be all the greater, in fact, because not only does the inertial mass have great effective inertia (and hence an inherent resistance to being drawn upward), but, when the converter is in a wave trough, the inertial mass can furthermore have a downward momentum developed during the converter's earlier descent into the wave trough under gravity. Any such downward momentum must be halted or exhausted before the inertial mass can be drawn upward.
  • the distance between the flotation module and the inertial mass can increase as the flotation module rises.
  • a significant tension can develop in at least the portion of the depending connector 1-150 connecting the flotation module to the inertial mass. This tension can create a net torque in pulley/capstan 1-125, causing it to turn in a first direction, and enabling the generator shaft to turn and the generator to generate electricity. Because of countertorque or resistance provided by the generator, the shaft does not turn freely. Some of the buoyant force acting on the flotation module will therefore be transmitted to the inertial mass via the depending connector. Accordingly, the inertial mass can develop an upward acceleration, albeit a lesser one than that developed by the flotation module or restoring weight.
  • any downward momentum previously possessed by the inertial mass has been exhausted, it can furthermore develop an upward momentum.
  • the flotation module Once the flotation module nears a wave crest, its upward movement can slow, i.e. it can develop a downward acceleration (e.g. by travelling upward at an ever slowing rate). Because the inertial mass can now have developed an upward momentum owing to an upward force transmitted to it by the depending connector, the distance between the flotation module and the inertial mass can begin to decrease. Accordingly, in the absence of the restoring weight or some other mechanism for taking up “slack" in the depending connector between the inertial mass and the flotation module, there would be a possibility for "slack" to develop in said connector. The restoring weight can "take up” this slack by causing the pulley/capstan to rotate in a second direction opposite to the first direction, essentially “rewinding" the pulley/capstan in preparation for another mechanical cycle.
  • Restoring weight 1-160 by contrast, has a relatively small mass and will tend to resist acceleration to lesser degree. Consequently, restoring weight 1-160 can be accelerated upward more rapidly and/or easily than inertial mass 1-140 and a net torque can be developed in pulley/capstan 1- 125, causing the pulley/capstan to rotate in a first direction, turning shaft 1-122, and enabling the generator to generate electricity.
  • Depending connector segment l-150b can shorten and depending connector segment l-150a can lengthen.
  • the distance between restoring weight 1-160 and the flotation module 1-105 can decrease, while the distance between the inertial mass 1-140 and the flotation module 1-105 can increase.
  • the inertial mass 1-140 can also in due course be accelerated upward and can eventually develop a significant upward momentum (even if, e.g. due to its relatively large mass, only a relatively small upward velocity).
  • the restoring weight can take up or limit the formation of "slack" in the depending connector and, assuming the countertorque or resistance provided by the generator is of a sufficiently small magnitude, the restoring weight' s descent can rotate the pulley/capstan 1-125 in a second direction, e.g. a direction opposite to the first direction in which it turned during the flotation module's earlier ascent.
  • the restoring weight can "rewind" the depending connector and allow a mechanical cycle to be completed, returning the device to a starting configuration.
  • FIG. 55 shows a perspective view of an embodiment of the current disclosure. In most respects this embodiment is identical to that of FIG. 54. There are two major differences. First, there is no restoring weight at 3-160. Instead, the depending connector
  • This motor can apply a constant torque, or can be provided with a control system that applies variable torque.
  • the motor can be the generator, i.e. the generator can function as both a motor and a generator. Or, the motor can be separate from the generator.
  • FIG. 56 shows a perspective view of an embodiment of the current disclosure. In most respects this embodiment is identical to that of FIG. 54. There are four major differences.
  • pulley/capstan 4- 125a pulley/capstan
  • Pulley/capstan 4- 125a is operatively connected to pulley/capstan 4- 125b by an integral/single shaft 4- 125c that passes through bearing housing 4-125d, which contains a bearing that bears said shaft 4- 125c. Because the two pulleys/capstans are operatively connected and/or integrated in this manner, they rotate at the same rate.
  • depending connector 4- 150a and depending connector 4- 150b.
  • aperture 4-115a and aperture 4-115b.
  • bearing housing 4-125d is supported on a beam, strut, truss, and/or other projection, that spans the embodiment's single aperture.
  • the pulleys/capstans are configured so that when depending connector 4-150a unwinds from pulley/capstan 4-125a, depending connector 4-150b winds up on pulley/capstan 4- 125b, and vice versa.
  • a rotation of shaft 4- 125c in a first direction is associated with one of the depending connectors winding up on its respective pulley/capstan and the other unwinding on its respective pulley/capstan.
  • a rotation of the shaft a second, e.g. opposite, direction is associated with the reverse.
  • the depending connectors 4-150a and 4-150b descend through apertures 4-115a and 4-115b
  • each of the depending connectors 4- 150a and 4- 150b is fixedly attached to its respective pulley/capstan.
  • one end of depending connector 4- 150a is attached to pulley/capstan 4- 125a at 4-125e. Accordingly, the depending connectors do not rely solely on friction for an operative connection with their respective pulleys/capstans.
  • generator housing 4-120 contains a flywheel that can store kinetic energy. Said flywheel is operatively positioned in the force-transmission pathway from the pulleys/capstans to the generator, smoothing the delivery of power to the generator.
  • FIG. 57 shows a perspective view of an embodiment of the current disclosure. In most respects this embodiment is identical to that of FIG. 54. There are two major differences.
  • restoring weight 5-160 is connected by connector linkage 5-158 to depending connector segment 5-150a.
  • Connector linkage 5-158 connects to depending connector segment 5-150a at connection point 5-159.
  • the addition of connector linkage 5-158 thus creates a "closed loop” consisting in part of depending connector 5-150 and in part of connector linkage 5-158.
  • This "closed loop” enables the device to passively enter an "inactive mode” as displayed in FIG. 58 in the event that inertial mass 5-140 descends beyond its nominal range. In this "inactive mode," the inertial mass cannot descend any further.
  • segment 5-150a ascends through aperture 5-115a, winds around an arc of pulley/capstan 5-125a, winds around an arc of pulley/capstan 5- 125b, winds around another arc of pulley/capstan 5- 125a, winds around another arc of pulley/capstan 5-125b, and so on, before descending (as segment 5-150b) to restoring weight 5-160.
  • the depending connector can wrap around both pulleys/capstans, a potentially simpler system of grooves can be used on each capstan (e.g. simple non-spiral circumferential grooves).
  • FIG. 58 shows a perspective view of the same embodiment shown in FIG. 57.
  • the embodiment has entered an "inactive mode" wherein the inertial mass has descended to a maximum separation from the flotation module.
  • the "closed loop” formed by the depending connector 6-150 and the connector linkage 6-158 is, at least at times, fully taut.
  • FIG. 59 shows a perspective view of a pulley 200 that illustrates the pulling of the pulley's associated cable 208 from a range 207 of directions confined to the pulley's plane of rotation 203 turn 202 the pulley, and potentially impart rotational kinetic energy and/or torque to it, while minimizing damage to either the pulley or the cable.
  • FIG. 60 shows a top-down view of the same pulley illustrated in FIG. 59. So long as the cable 204 and/or 205 is pulled from a direction that lies within the pulley's plane of rotation 203, damage to the pulley and the cable are minimized.
  • FIG. 61 shows a top-down view of the same pulley illustrated in FIGS. 59 and 60.
  • the pulley's respective cable 210 is being pulled from a direction that is outside (e.g. by an angle of 211) the pulley's plane of rotation 203.
  • the cable is pulled out of 212, and/or away from, the center of the pulley. This may cause the cable to be abraded (e.g. at 213) as it is pulled across the lateral edge of the pulley.
  • the resulting torque 214 between the pulley and its shaft and/or supporting bearings may also cause damage and/or fatigue.
  • FIG. 62 shows a side cross-sectional illustration of a buoy 320 connected to a submerged inertial mass 324 by a cable 325, that is driven along a circular path by waves 328 passing through the surface 328 of a body of water on which the buoy floats. Note that the angular orientation of the cable is not coaxial with a vertical normal axis passing through the center of the buoy.
  • the axis passing through the center of the buoy and normal to its horizontal plane will be referred to as the buoy's "inertial mass alignment axis.”
  • the buoy's inertial mass alignment axis passes through the center of the inertial mass 324 when the buoy is at the crest 320 and the trough 322 of a wave.
  • the center of the inertial mass is no longer located on, and/or coaxial with, the buoy's inertial mass alignment axis.
  • FIG. 63 shows a top-down view of the buoy illustrated in FIG. 62 and moving in response to wave motion.
  • the buoy 320 will typically move back-and-forth 335, e.g. from positions 321 to 323, in response to a wave-induced movement.
  • the point here is that the lateral oscillations of a buoy will typically be within a vertical plane that is parallel to the direction 329 of wave motion. And, those lateral buoys oscillations will typically be within a plane that is normal to the wave front, e.g. 334.
  • FIG. 64 illustrates that with respect to the perspective of a buoy 340, its lateral oscillations with respect to its attached inertial mass 345 will appear to be equivalent to a lateral oscillation of the inertial mass, e.g. through an angular range of 346.
  • FIG. 65 illustrates that with respect to the perspective of a buoy 340, its lateral oscillations with respect to its attached inertial mass 345 will appear to be equivalent to a lateral oscillation of the inertial mass, e.g. through an angular range of 346.
  • the plane i.e. the plane of the page
  • the inertial mass 345 appears to rotate in this case is normal to the plane of the pulley's 343 rotation.
  • FIGs. 66 and 67 are close-up views of the pulleys and relative cable movements that were illustrated in FIGS. 64 and 65 respectively.
  • FIG. 68 illustrates a buoy oscillating with wave motion.
  • the buoy is rotating so as to preserve the alignment of the center of the inertial mass 361 with the buoy's inertial mass alignment axis.
  • Such a pattern of movement by a buoy would be expected to reduce wear and/or damage to a respective cable, and a respective pulley, if it were possible to achieve.
  • the buoy has only a single, center cable that, because it is near the buoy's center of mass and center of rotation, would presumably be unable to achieve a moment arm and torque on the buoy sufficient to rotation the buoy so as to preserve the relative orientation of the inertial mass 361 along its inertial mass alignment axis.
  • FIG. 69 illustrates a buoy oscillating with wave motion in a manner similar to the one illustrated in FIG. 68.
  • the cross-sectional shape of the buoy is hemi-circular. This hull shape would be expected to allow the buoy to be rotated so as to preserve the relative position of its associated inertial mass 384 without the concomitant generation of counter-torque, since the buoyancy and center of buoyancy of the buoy are relatively unchanged due to a rotation of the buoy over a certain range of angles (and the buoy can be made easier to rotate still if its center of mass is located near its center of rotation or metacenter).
  • FIG. 70 shows a side view of an embodiment of the current disclosure.
  • a buoy 400 is equipped with two pulleys 404 and 405 on opposite sides of the buoy.
  • One end of cables 402 and 403 are connected to these pulleys.
  • the other ends of the cables are connected to inertial mass 406.
  • the cables segments 402 and 403 lengthen when the buoy is lifted by a wave, and the respective pulleys 404 and 405 are turned (e.g. thereby turning generators and generating electrical power) so as to deploy additional cable.
  • the torque on each pulley is regulated and/or controlled so as to continuously "point" the buoy's inertial mass alignment axis toward the center of the inertial mass 406.
  • the lengths of cable segments 402 and 403 will remain equal, i.e. even as the lengths of those cable segments increase and decrease they will remain equal.
  • FIG. 71 shows a side view of an embodiment of the current disclosure. This figure illustrates how, when being lifted 422 by a wave, an increase in the relative torque, and/or the relative resistance of the pulley to the lengthening of cable segment 424, can impart a torque 429 to the buoy about its center of mass and preserve the alignment of its inertial mass alignment axis with respect to the inertial mass.
  • FIG. 72 shows a side view of a buoy of an embodiment of the current disclosure.
  • the buoy 440 floats adjacent to the surface 441 of a body of water.
  • the buoy has a center of gravity (COG), and/or a center of mass (COM), that is located within a certain radial distance of the center of the buoy 442.
  • COG center of gravity
  • COM center of mass
  • Another embodiment has a COG and/or a COM, e.g. 445, that is located at a point within the buoy, wherein that point lies within a cylindrical space centered about, and within a radial distance 444 of, the vertical longitudinal axis of the buoy.
  • FIG. 73 shows a perspective view of an embodiment of the current disclosure.
  • a buoy 540 is radially symmetrical about a vertical axis through its center, and every cross-section through the buoy has an approximately hemi-circular shape with respect to a vertical plane passing through its center. Note that the pulleys 544-547 are arranged and/or aligned such that the plane of rotation of each passes through the central vertical axis of the buoy.
  • FIG. 73 shows a top-down view of the embodiment of the current disclosure illustrated in FIG. 73.
  • FIG. 75 shows a side view of the embodiment of the current disclosure illustrated in FIG. 73 as it moves responsive to a wave motion.
  • FIG. 76 shows a perspective view of an embodiment of the current disclosure.
  • a buoy 560 is approximately radially symmetrical about a vertical axis through its center, and every cross-section through the buoy has an approximately hemi-circular shape with respect to a vertical plane passing through its center.
  • this embodiment utilizes four sets of interlinked and/or coaxial pulleys.
  • Each set of three pulleys e.g. 564
  • Each three-pulley shaft is also connected at outer ends to a pulley upon which cables to "slack-minimization" weights, e.g. 567, are connected.
  • the associated and/or rotatably connected slack- minimization weights are lifted. Then, when the buoy is moving closer to the inertial mass, e.g. when moving toward the trough of a wave, the slack-minimization weights descend and their gravitational potential energy is used to rewind the pulley cables.
  • FIG. 77 shows a top-down view of the embodiment of the current disclosure illustrated in FIG. 76.
  • FIG. 78 shows a perspective view of the embodiment of the current disclosure similar to the one illustrated in FIGS. 73-75.
  • the cables, e.g. 608, that connect the pulleys, e.g. 603, to the inertial mass 610 pass through apertures and/or channels which have openings, e.g. 607, adjacent to a pulley, and, e.g. 609, near the bottom of the buoy.
  • FIG. 79 shows a cross-sectional view of the embodiment of the current disclosure illustrated in FIG. 78, and taken along a vertical plane passing through the center of the buoy and through a pair of opposite pulleys.
  • FIG. 80 shows a perspective view of an embodiment of the current disclosure.
  • a buoy 450 has a hemi-circular cross-section 452 with respect to one horizontal axis 454, and a linear (i.e. a cylindrical) shape with respect to the other horizontal axis 460.
  • the hemi-circular cross-section facilitates the rotation 453 of the buoy about axis 454.
  • the buoy will tend to resist rotation 459 about the other axis 460.
  • the embodiment utilizes pulleys, e.g. 455 and 456, which are characterized by planes of rotation that are parallel to axis 454 and normal to axis 460.
  • pulleys e.g. 455 and 456, which are characterized by planes of rotation that are parallel to axis 454 and normal to axis 460.
  • FIG. 81 shows a side view of the embodiment of the current disclosure illustrated in FIG. 80 as it oscillates with a wave. Note that with respect to this perspective, i.e.
  • FIG. 82 shows a side view of the embodiment of the current disclosure illustrated in FIG. 80 as it oscillates with a wave. Note that with respect to this perspective, i.e. from a perspective along axis 454, the buoy's angular orientation rotates, i.e. through the imposition of differential torques across opposing pairs of pulleys. The angular orientation of the buoy (with respect to this axis and this perspective) is controlled and adjusted so as to preserve the alignment of the buoy's inertial mass alignment axis and the center of the inertial mass 457.
  • FIG. 83 shows a top-down view of the embodiment of the current disclosure illustrated in FIG. 80.
  • the buoy 450 is connected, by means of pulleys, e.g. 455-456, 495, and 497, and their respective cables, e.g. 494, to a submerged inertial mass 457.
  • FIG. 84 shows a perspective view of an embodiment of the current disclosure.
  • a buoy 510 has a hemi-circular cross-sectional shape with respect to a plane normal to a lateral axis 513, and a linear (and/or cylindrical) cross-sectional shape with respect to a plane normal to a lateral axis 516.
  • This embodiment is similar to the one illustrated in FIGS. 80-83, except that the pulleys are located along the hemi-circular sides of the buoy (instead of the along the linear sides of the buoy as in FIGS. 80-83).
  • FIG. 85 shows a side view of the embodiment of the current disclosure illustrated in FIG. 84 as it oscillates with a wave. Note that with respect to this perspective, i.e. from a perspective along axis 516, the buoy's angular orientation does not change to a noticeable extent. Instead, the cables oscillate back-and-forth within the plane of rotation of each respective pulley.
  • FIG. 86 shows a side view of the embodiment of the current disclosure illustrated in FIG. 84 as it oscillates with a wave. Note that with respect to this perspective, i.e. from a perspective along axis 513, the buoy's angular orientation rotates, i.e. through the imposition of differential torques across opposing pairs of pulleys, e.g. through the imposition of a greater torque to pulley 518C than to 519C, and/or through the imposition of a greater torque to pulley 519B than to 518B.
  • FIG. 87 shows a top-down view of the embodiment of the current disclosure illustrated in FIG. 84.
  • the buoy 510 is connected, by means of pulleys, e.g. 518-519, and 522-523, and their respective cables, e.g. 520, to a submerged inertial mass 526.
  • FIG. 88 shows a side perspective of the directional rectifying pulley 1002, hollow connecting arm 1003, and traction winch 1006/1008, that characterize the embodiments illustrated in FIGs. 22-28.
  • a directional rectifying pulley 1002 is mounted to an upper surface of a buoy 1000, and is rotatably connected to, and/or mounted on, an opposing pair of bracket arms, e.g. 1013. Those bracket arms are attached to, and/or integral with, a hollow cylindrical tube 1003. And that tube 1003 is rotatably connected to a radial bearing 1004, mounted atop a strut 1014, that allows the tube 1003 to rotate about the tube's longitudinal axis.
  • a cable 1010 is connected to a submerged inertial mass (not shown). If the relative position of the inertial mass moves within the plane of the figure's page, i.e. within the plane of the directional rectifying pulley's 1002 plane of rotation (which is coplanar with the page), then the cable will tend to vary its position in a manner represented by the various cable positions 1010-1012 included within the illustration. In other words, the cable will tend to move 1009 within the plane of the page. [00303] A change in the angular position at which the cable 1010 enters the "groove" of the pulley (i.e.
  • FIG. 89 shows the same directional rectifying pulley illustrated (from a side perspective) in FIG. 88. However, in FIG. 89, the directional rectifying pulley 1002 is illustrated from a front perspective.
  • the vertical and/or upright orientation of the pulley 1002 is the same as its orientation in FIG. 88.
  • the cable 1011 is aligned with a plane at 1017, and normal to the page, that is coplanar with the pulley's plane of rotation. Note that the cable passes over the top of the pulley, and then into the interior of the cylindrical hollow connecting arm, at the location specified by the intersection of the lines 1017 and 1019.
  • the hollow connecting arm rotates within a radial bearing 1004.
  • FIG. 90 shows the same directional rectifying pulley illustrated and discussed in relation to FIGs. 88 and 89.
  • the directional rectifying pulley 1002 illustrated in FIG. 90 is illustrated from a front perspective.
  • FIG. 90 illustrates the change in angular orientation of the directional rectifying pulley 1002 in response to a "sideways" pulling of the cable 1011, i.e. a downward pulley of the cable that, at least partially, pulls the cable out of the plane normal to the page and passing through line 1017. In this case the cable has been pulled 1021 from the plane at 1017 to a plane at 1022.
  • the pulley's axis of rotation 1021 is about an axis normal to the page and passing through the planes normal to the page and intersecting the page at lines 1017 and 1019, the point 1015 at which the cable leaves the pulley and travels on to the traction winch remains unchanged.
  • the directional rectifying pulley herein disclosed avoids the cable damage and wear frequently attributed to "excessive fleet angle," i.e. to angles at which a cable approaches and enters a pulley that cause the cable to abrade the sharp edges of a pulley.
  • FIG. 91 shows a vertical cross-sectional view of an embodiment of the present disclosure.
  • Floatation module 91-1 is a directional rectifying buoy and is shown to be floating in body of water 91-2.
  • Pulleys/sheaves/drums 91-3 are inset into the OML of floatation module 91-1.
  • Shafting not shown runs through the cylindrical axes of drums 91-3 and is coupled to shafting in PTO module 91-8.
  • PTO module 91-8 may be an electrical generator, gearbox, hydraulic pump, brake, or any number of other mechanical devices or combinations thereof.
  • the common feature of any component options comprising PTO module 91-8 is that they can provide torque opposite the direction of drums' 91-3 rotation. This countertorque provides the resistance which allows power to be extracted from the rotating drum.
  • Flexible connectors 91-4 consist of many individual strands of wire, cable, chain, rope, etc. arranged in a linear array such that they resemble a ribbon. Flexible connectors 91-4 pass over and around drums 91-3, but cannot slip relative to the surface of drums 91-3. This can be accomplished by wrapping the flexible connector several times on the drum and fixing its end, or a portion of it, to the drum surface, or to a radially protruding feature at the drum surface (such as a bracket or tooth). This implies that linear motion of flexible connectors 91-4 will cause rotative motion of drums 91-3.
  • the flexible connectors located outboard of drums 91-3 transit to, and interface with, confluence structure 91-7, which is ring shaped and contains an aperture in its center.
  • Mating connectors 91-10 which may be single elements or ribbon arrangements, transit from confluence structure 91-7 and interface to, wrap around, or otherwise mate with spherical inertial mass (IM) 91-11.
  • IM 91-11 is shown to have a rigid outer shell with aperture 91-9 located at its top-center.
  • IM 91-11 is filled with water and has a positive net weight in water that would cause it to sink if not restrained. Or, in some
  • IM 91-11 is made neutrally buoyant or buoyant by filling voids in its walls with foam or air.
  • Flexible connectors 91-4 located inboard of drums 91-3 transit down and are mated to ribbon spreader structure 91-6.
  • ribbon spreader structure (“ribbon junction bar”) 91-6 is a flexible linear distribution of weight 91-5 which may be chain, wire, weights hung from rope, or any of a multitude of
  • the chain 91-5 passes through the IM aperture 91-9 and some of the chain 91-5 may be resting on the bottom of the IM (91-12), adding to the net weight of the IM itself (91-11).
  • the distribution of weight between the IM 91-11 and chain 91-5 can be such that in a situation with no forces being imparted by the environment or PTO module 91-8, that the system can find equilibrium. This happens due to the IM 91-11 falling until enough chain 91-12 (weight) is picked up off the IM's bottom 91-12 (thereby reducing the net weight of the IM) and subsequently hung from ribbon spreader structure 91-6 which increases the weight counteracting the fall of the IM.
  • This has the advantageous feature of being a passive "off configuration which the system can obtain in the event of a failure, or merely in calm, waveless conditions.
  • FIG. 92 shows a vertical cross-sectional view of an embodiment of the present disclosure.
  • Floatation module 92-1 is shown to be floating in body of water 92- 2.
  • the IM 92-11 in this embodiment is shown to have a truncated teardrop shape.
  • floatation module 91-1 is not of a directional rectifying form. Instead, directional rectifying pulleys 91-7 are used, which allow flexible connectors 92-4 to always feed onto the groove in pulley 91-7 without an incident angle, regardless of the angle of flotation module 91-1 or its relative position or angle to IM 92-11.
  • Flexible connector 92-4 is shown to be constructed of a single tensile element. This may be a rope, wire, cable, chain, or other material/construction. Flexible connector 92-4 interfaces with drums 91-3 by having multiple wraps around the outside surface of each in a manner similar to a traction winch.
  • FIG. 93 shows a perspective view of an embodiment of the present disclosure, from a vantage point above and to the side of the embodiment.
  • the flotation module 2300 floats adjacent to the surface of a body of water (not shown).
  • a flexible connector 2301/2308 is wound many times around a two-shaft rotating capstan 2303, which is similar to a traction winch.
  • the flexible connector 2301 descends from the two- shaft rotating capstan 2303, through a vertical aperture 2302 near the center of flotation module 2300.
  • One end of connector 2301 is connected to a float (i.e., a buoyant object) 2310.
  • Another flexible connector 2314, or another portion of the same flexible connector 2301 connects the float 2310 to an "inertial mass" 2315.
  • the inertial mass 2315 is a water-filled vessel that has a substantial mass (i.e., due largely to the water inside). Taking into account the water inside the inertial mass and also taking into account any "inertial mass weighted portion" that may be included in or be affixed to or that may depend from the inertial mass, the inertial mass in this embodiment has a greater average density than water.
  • its average density will typically be not very much greater than water (e.g., it can be in the range of 1020 to 1080 kg per cubic meter, but can also be outside this range), so that its "net weight” (i.e., the gravitational weight of the vessel including the water inside, less the buoyant force upon it owing to its displacement, i.e., the gravitational weight of the vessel including the water inside less the gravitational weight of an equivalent volume of water) while appreciable in everyday terms, is far, far smaller than the net weight of a similarly sized object made of a material such as concrete or steel. Consequently, the inertial mass can have a large inertia, but impose relatively small buoyancy requirements on the flotation module.
  • a three- shaft capstan or traction winch is used.
  • a four-shaft capstan or traction winch is used.
  • the flexible connector is wound around all capstans in an analogous manner to the manner in which it is wound around the two capstans here.
  • the multiple capstans are positioned so that their longitudinal axes are parallel, and so that they are not coplanar, i.e., the winding of the flexible connector over a three-shaft capstan approximately traces out a triangle.
  • the rotating capstans (or chainwheel, or spiral capstan, as applicable) is/are fully or partially submerged in the body of water. It/they can, for instance, be affixed to a bottom, rather than a top, surface of the flotation module.
  • the "restoring weight” 2309 is an object having a relatively small mass, but due to its having a relatively great density, it has a relatively small, but significant and positive, net weight in water. Its purpose is to help “rewind” or “reset” the flexible connector 2308, or in other words to take up slack in it.
  • inertial mass 2315 is able to fall under its own net weight, although there may be a delay in its assuming a downward momentum due to its relatively large mass and hence relatively large upward inertia.
  • any slack in connector 2301 is removed by the downward force imparted to flexible connector 2301, 2303, 2304, and 2308 by restoring weight 2309.
  • inertial mass 2315 is, at least in part, countered and/or offset by the upward buoyant force exerted on inertial mass 2315 by float 2310.
  • any offset weights, e.g., 2313, that hang from float 2310 diminish the amount of buoyant force that the float 2310 exerts on inertia mass 2315, effectively reducing the net weight of the inertial mass 2315.
  • any offset weights e.g., 2311, that instead hang from flotation module 2300, do not diminish the amount of buoyant force that the float 2310 exerts on inertial mass 2315.
  • Any offset weight, e.g., 2312, whose net weight is supported in part by the buoyancy of the float 2310 and in part by the buoyancy of the flotation module 2300 will impart a corresponding fraction of its net weight to the float 2310, and, by that degree, diminish the degree to which the float 2310 reduces the effective net weight of the inertial mass 2315.
  • the effective net weight of the inertial mass 2315 to be adjusted, tuned, altered, and/or optimized, by directing the control system, e.g., inside power take-off 2305, to raise or lower the average depth of the inertial mass (e.g., by converting less or more, respectively, of the available wave energy to electrical power, leaving more or less, respectively, of the available wave energy to impart an upward momentum to the inertial mass), and therefore raise or lower the average depth of the float 2310.
  • Module 2305 contains a generator and/or other power take-off which converts at least some of the rotational kinetic energy and/or torque manifested in capstan/shaft 2303 into electrical power.
  • Modules 2306-2307 may contain additional power take-offs and sensors (e.g., of angular frequency, of torque, of angular displacement or velocity or rotation rate, of the shaft/capstan 2303, etc.).
  • FIG. 94 shows a side view of the same embodiment of the present disclosure that is illustrated in FIG. 93, where the walls of the flotation module 2300 have been made partially transparent for the sake of illustration. The frustoconical walls of apertures 2302 (see FIG. 93) are visible.
  • FIG. 95 shows a perspective top-down view of the same embodiment of the present disclosure that is illustrated in FIGs. 93 and 94.
  • Flexible connector 2301 descends from capstan shaft 2303 and passes through aperture 2302 where it connects to float 2310, and thereafter (perhaps indirectly through float 2310) to inertial mass 2315. After passing over and on to shaft 2303 of the capstan, flexible connector 2301 is wound 2319 and 2318 over the two capstan shafts (in a spiraling fashion) approximately nine times, after which the other end of the flexible connector descends from capstan shaft 2304 and passes through aperture 2320 where it connects to restoring weight 2309. Rotating capstan shafts 2303 and 2304 each have a series of raised ridges forming inset sheaves in which segments of connector 2301 can run.
  • module 2305 is a power take-off and control system, including a generator and a suite of sensors (for the angular position and velocity of the capstan) and control system circuits.
  • the resistive torque (and the electrical power) generated by a generator 2305 A is controlled by a power control subassembly 2305B.
  • 2306 is a brake that can apply a braking resistance to the capstan, e.g., without generating electrical power.
  • the generator 2307 is operatively connected to capstan 2304.
  • FIG. 96 shows a perspective side view of the flotation module of the same embodiment of the present disclosure that is illustrated in FIGs. 93-95.
  • FIG. 97 shows a perspective view of another embodiment of the present disclosure.
  • a flotation module 2700 floats adjacent to the surface 2701 of a body of water. Descending from one shaft 2707 of a two-shaft capstan (around which a flexible connector is wound many times), through a vertical aperture 2709, is a flexible connector 2710. The deep end of connector 2710 is connected to a float (i.e., a buoyant object) 2711. Another flexible connector 2712, or another portion of the same flexible connector 2710, connects the float 2711 to an "inertial mass" 2713.
  • a float i.e., a buoyant object
  • the inertial mass 2713 is connected to flexible cable 2712 by a "net” 2714 (which can be a sling, or a mesh of cords that entrap the inertial mass 2713).
  • the inertial mass 2713 is a water-filled vessel that has a substantial mass (i.e., due largely to the water inside) and a relatively smaller "net mass” (i.e., the mass of the vessel less the mass of an equivalent volume of water).
  • This flexible connector 2715 is connected to a restoring weight 2716.
  • the restoring weight 2716 is an object with a relatively small mass, but due to a relatively great density, a significant and positive net weight.
  • Flotation module 2700 capstan power take-off assembly 2702-2704, 2706- 2708, float 2711, restoring weight 2716, offset weights 2718-2720, and inertial mass
  • This embodiment controls and/or adjusts the effective net weight of its inertial mass 2713 by controlling the degree, duration, and/or timing, of its capstan- mediated resistance of the movements of flexible connector 2710 / 2715 across and/or around its shafts.
  • the float 2711, inertial mass 2713, and at least some of the offset weights 2719 may be raised to a lesser depth, for example, by converting some of the kinetic energy of the waves into an upward momentum of the inertial mass, via a tension in connector 2710.
  • the float 2711, inertial mass 2713, and offset weights 2719 may be lowered to a greater depth (i.e., by allowing them to fall under the gravitational force that draws them to a lower, equilibrium position).
  • This control can be intermediated by a control system, and the degree of resistance can be modified autonomously by the converter itself (in response to sensor readings) or by external intervention, e.g., upon the receipt of encoded commands from a satellite.
  • This embodiment can also use a motor 2702 to raise and lower the inertial mass, even in the absence of waves. This motor can be connected to a control system and remotely controlled, e.g., by satellite.
  • FIG. 98 shows a perspective view of the same embodiment of the present disclosure as is illustrated in FIG.
  • FIG. 99 shows a perspective view of the same embodiment of the present disclosure as is illustrated in FIGs. 97 and 98, but the average depths of the float 2711 and the inertial mass 2713 have been further decreased (i.e., they have been pulled up even further than illustrated in FIG. 97). This has caused, relative to the configuration illustrated in FIG. 97, all of the offset weights, e.g., 2718, to have their net weights supported by float 2711. This this configuration, the effective net weight of inertial mass 2713 has been increased to the maximum possible extent.
  • FIG. 100 shows a perspective view of the what is essentially the same embodiment of the present disclosure as is illustrated in FIGs. 97-99.
  • the string of offset weights has been replaced by a length of chain, 2718- 2720, or other dense flexible elongate element, in particular, a dense flexible elongate element with a greater net weight per unit length than the flexible connector 2724.
  • FIG. 101 shows a perspective view of an embodiment of the present disclosure.
  • This embodiment is similar to the one illustrated in FIGs. 97-99, but instead of utilizing and/or incorporating a capstan composed of, and/or incorporating, two shafts, the power take-off of the embodiment illustrated in FIG. 101 has a power take-off that incorporates a single pulley or chainwheel 3802 that is rotatably connected to at least one generator 3802. Unlike the embodiment illustrated in FIGs. 97-99, the embodiment illustrated in FIG. 101 has only a single aperture (under chainwheel 3802).
  • Flexible connector 3804A/B is a chain or some other kind of line that has protuberances or other non-uniform surface features that enable it to interface with chainwheel 3802 and apply a tangentially-directed force (torque) thereto in excess of the force supplied by friction alone.
  • the adjustment of the disposition of the offset weights 3809-3811 is achieved through the control (e.g., the timing, duration, and/or magnitude) of the resistive torque applied to pulley 3802 by the embodiment's power take-off 3803, and associated (e.g., embedded) control system. As was discussed in relation to FIGs.
  • this method of controlling the effective net weight of the inertial mass 3902 might be characterized as "passive” and/or “coupled.”
  • the embodiment configuration illustrated in FIG. 101 has the offset weights, e.g., 3809, to the left of inflection point 3810 offsetting and/or reducing the net effective buoyancy of float 3808, and thereby enhancing and/or increasing the net effective net weight of inertial mass 3805.
  • FIG. 102 shows a perspective view of an embodiment of the present disclosure. Similar to the embodiment illustrated and discussed in relation to FIGs. 97- 99, the embodiment illustrated in FIG. 102 utilizes a capstan composed of, and/or incorporating, two shafts. However, whereas the embodiment illustrated in FIGs. 97-99 controlled the effective net weight of its inertial mass indirectly through the "passive" and/or “coupled” control of the average depth of the associated float, this embodiment directly controls the depth and configuration of its offset weights 3910.
  • a motor 3913 releases or retracts flexible connector 3911 (through an aperture 3919) so as to shift the position of the inflection point (i.e., near offset weight 3910F) which determines which and how many offset weights, e.g., 3910A (if any), will diminish the effective buoyancy of float 3905, and therefore which and how many offset weights will indirectly increase the effective net weight of inertial mass 3902. Also, because offset weights 3910 are not tethered directly to the restoring weight 3917 (as is true of the embodiment illustrated in FIGs. 27-29), restoring weight 3917 is freely suspended from flexible connector 3916. [00354] The embodiment configuration illustrated in FIG. 102 has offset weights
  • FIG. 103 shows a perspective view of the same embodiment of the present disclosure as is illustrated in FIG. 102. Unlike the embodiment configuration illustrated in FIG.
  • the length of flexible connector 3911 in the embodiment configuration illustrated in FIG. 103 is greater (the motor 3913 having unspooled a portion of this connector from 3912), while the average depth of float 3905 is approximately the same.
  • the addition of the net weight of the four additional offset weights to the float 3905 has the effect of diminishing the buoyant force imparted by float 3905 to inertial mass 3902, thereby increasing the effective net weight of inertial mass 3902.
  • FIG. 104 shows a perspective view of a similar embodiment of the present disclosure as is illustrated in FIG. 103, but has no restoring weight (e.g., 3917), nor a corresponding flexible connector (e.g., 3916) and aperture (e.g., 3918). Rather, converter 4100 has a flexible connector wound about shaft, pulley, and/or single-shaft capstan, 4102. One end of that connector descends through aperture 4105 where it is connected to float 4107. The other end is connected to the shaft, pulley, and/or single- shaft capstan, 4102, or is otherwise constrained or attached at the flotation module 4100. [00357] Restoring weight 3917, in the embodiment illustrated in FIG.
  • FIG. 104 causes the flexible connector connecting the flotation module to the float to be retracted, and will promote the removal of slack from flexible connector 3906, following the passage of a wave crest, and/or during the downward movement of the flotation module.
  • the embodiment illustrated in FIG. 104 has no restoring weight. Instead, a motor 4104 applies a "rewinding" torque to shaft 4102 supplanting the function of a restoring weight. This rewinding torque can be constant or intermittent, and can be (but need not be) under the influence of (turned on and off by, or having a strength modulated by) a control system.
  • FIG. 105 shows a perspective view of an embodiment of the present disclosure that is similar to the one illustrated and discussed in relation to FIGs. 97-99. Whereas the embodiment illustrated and discussed in relation to FIGs. 97-99 has a float 2711 and an inertial mass 2713 that are flexibly connected by a flexible connector 2712, the embodiment illustrated in FIG. 105 has a float 4505 and an inertial mass 4507 that are rigidly connected by a truss 4506.
  • FIG. 106 shows a perspective view of another embodiment of the present disclosure. It is similar to the embodiment illustrated and discussed in relation to FIGs. 97-99 in that it controls the effective net weight of one of its components indirectly through the "passive" and/or “coupled” control of the average depth of the associated component. However, it differs from that embodiment in that it lacks a float. And, it differs from that embodiment in that the target of its control is the restoring weight (instead of the inertial mass). [00360] The embodiment illustrated in FIG. 106 does not control the effective net weight of its inertial mass 4604. Instead, it controls the complementary effective net weight of its restoring weight 4607.
  • inertial mass 4604 is a concrete shell filled with water. In one embodiment, inertial mass 4604 is, or has a shell, composed of a hybrid mixture of concrete and closed cell or open cell (e.g., poly-urethane) foam. In one embodiment, inertial mass 4604 is a mixture of metals and plastics. In one embodiment, inertial mass 4604 was printed with reinforced concrete by a 3D printer and filled with water after its printing.
  • restoring weight 4607 and offset weights 4609 are made of iron. In another embodiment, they include concrete. And, in another embodiment, they are made of material(s) that include plastics. [00365]
  • Module 4612 contains a generator and/or other power take-off which converts at least some of the rotational kinetic energy and/or torque manifested in capstan shaft 4602 into electrical power. Modules 4614 and 4615 may contain additional power take- offs, sensors (e.g., of angular frequency, of torque, of angular displacement, etc.).
  • Ultrasonic sensor 4611 projected outward from the converter on an arm, is directed downward toward the ocean surface and measures the approximate distance between itself and the water level, providing the device' s control system with real-time readings of the approximate draft or waterline height of the device.
  • a capacitive sensor is used to measure the height of the waterline.
  • Two other similar sensors are located around the periphery of the device. [00367] As shown in FIG. 107, which shows the same embodiment as FIG. 106, aperture 4601 is visible and flexible connector 4603 descends from capstan shaft 4602 through aperture 4601 where it connects to inertial mass 4604.
  • FIG. 108 which shows the same embodiment as FIG. 106, shows apertures 4601 and 4617, and flexible connector 4603 descends from capstan shaft 4602 through aperture 4601 where it connects to inertial mass 4604 (not shown). Flexible connector 4606 descends from capstan shaft 4605 through aperture 4617 where it connects to restoring weight 4607.
  • a sensor mounted and/or attached to a bottom surface of flotation module 4600 is a sensor that provides the embodiment' s control system with measurements of the relative depth and/or distance of the inertial mass 4604 (not shown) below the flotation module 4600.
  • the senor 4618 is a sonar (i.e., echo-locating) sensor.
  • sensor 4618 is a camera that measures the distance between two lights mounted at a known separation on the inertial mass 4604. Measurements of the relative separation of the two lights allows the distance of the inertial mass to be computed. Other embodiments utilize other kinds of sensors to determine the relative depth of the inertial mass.
  • FIG. 109 shows a perspective view of the same embodiment of the present disclosure that is illustrated in FIGs. 106-108.
  • the embodiment is in a configuration in which the relative depth of the restoring weight 4607 has been decreased (relative to its depth in the configuration illustrated in FIGs. 106-108).
  • FIG. 110 shows another perspective view of the same embodiment of the present disclosure that is illustrated in FIGs. 108 and 109.
  • apertures 4601 and 4617 are visible on the upper surface of the flotation module 4600.
  • Flexible connector 4603 descends from capstan shaft 4602 through aperture 4601 where it connects to inertial mass 4604.
  • FIG. I l l shows a bottom-up perspective view of the same embodiment of the previous figure, where apertures 4601 and 4617 are visible.
  • Flexible connector 4603 descends from capstan shaft 4602 through aperture 4601 where it connects to inertial mass 4604 (not shown).
  • Flexible connector 4606 descends from capstan shaft 4605 through aperture 4617 where it connects to restoring weight 4607.
  • a sensor mounted and/or attached to a bottom surface of flotation module 4600 is a sensor that provides the embodiment' s control system with measurements of the relative depth and/or distance of the inertial mass 4604 (not shown) below the flotation module 4600.
  • the sensor 4618 is a sonar (i.e., echo-locating) sensor.
  • sensor 4618 is a camera that measures the distance between two lights mounted at a known separation on the inertial mass 4604. Measurements of the relative separation of the two lights allows the distance of the inertial mass to be computed. Other embodiments utilize other kinds of sensors to determine the relative depth of the inertial mass.
  • FIG. 112 illustrates an embodiment of the current disclosure.
  • a flotation module 131 floats adjacent to the surface 130 of a body of water.
  • a pair of weights 142- 143 are suspended below flotation module 131 by connectors 134 and 137, respectively.
  • Suspended above weights 142-143 is an inertial mass 138, which, in one embodiment, is buoyant.
  • Suspended from inertial mass 138 via connector 135-136 and over pulley 132 is a weight 139. As inertial mass 138 moves downward, away from flotation module 131, increasing the distance between inertial mass 138 and flotation module 131, connector segment 135 is pulled and its length is increased.
  • connector segment 136 is shortened, weight 139 is raised, and brought into closer proximity to flotation module 131.
  • the passage of connector 136 across and/or over pulley 132 so as to add length to connector segment 135 causes pulley 132 to rotate providing the opportunity to engage, energize, and/or rotate the shaft of, generator 133 which is operably connected to pulley 132.
  • inertial mass In its nominal configuration, e.g. while resting at the surface 130 of a body of water in the absence of waves, inertial mass, due to its buoyancy and/or the upward pull of connector segment 135 resulting from the gravitational force imparted to it by weight 139, will rise until prevented stopped by connectors 140-141.
  • the combined weight of weights 142-143 is sufficient to counter the tendency of inertial mass 138 to rise.
  • the flotation module 131 and the weights 142-143 descend, typically in a sinusoidal fashion. Because of the insufficiency of its upward buoyancy, and/or the upward force indirectly imparted to it by weight 139, weights 142-143 pull inertial mass 138 down in synchrony with them, and with flotation module 131. However, at the point in the wave's motion, and therefore in the motions of the flotation module 131, and its connected weights 142-143, where their downward acceleration switches to an upward acceleration, e.g. slowing their descent and eventually causing their ascent, the inertia of the inertial mass 138 is sufficient to cause it to continue its downward movement, despite the opposing gravitational force of weight 139, and even its own buoyancy (if any).
  • inertial mass While inertial mass is compelled by the excessive downward gravitational force of weights 142-143 to follow weights 142-143, and, by extension, the flotation module 131 to which they are connected, as they accelerate downward (following the wave's downward acceleration), it is not compelled to decelerate with them.
  • the only force that would oppose the otherwise unconstrained downward movement of the inertial mass 138 is connector segment 135.
  • the magnitude of its resistance to the lengthening of connector segment 138, and therefore and/or thereby the downward movement of the inertial mass 138 relative to flotation module 131, is the result of, and/or equal to, the gravitational force and/or weight of restoring weight 139, and the resisting torque imparted to pulley 132 by generator 133.
  • inertial mass 138 With a sufficiently heavy restoring weight 139, and/or a sufficiently great resistive torque imparted to pulley 132 by generator 133, inertial mass 138 will be unable to change the distance by which it is separated from the flotation module 131 above.
  • inertial mass 138 will be locked at its illustrated position relative to the flotation module 131 above, and the weights 142-143 below, through every part and/or portion of a wave cycle, and/or continuously.
  • FIG. 112 is representative of a large number of related embodiments that may be derived from this representative embodiment.
  • the numbers of variations and/or altered and/or similar embodiments that can be derived from, and/or represent relatively minor alterations to the representative embodiment illustrated in FIG. 112, include, but are not limited to, those in which: [00384] 1) Connectors 134/137 are representative of one or more connectors, and the scope of this disclosure includes embodiments possessing only one, or three or more connectors instead of the two connectors 134/137.
  • Connectors 140-141 are representative of one or more connectors connecting inertial mass 138 to weights 142-143, and the scope of this disclosure includes embodiments possessing any number of one or more connectors instead of the two connectors 140-141.
  • Weights 142-143 are representative of one or more weights, and the scope of this disclosure includes embodiments possessing only one, as well as those possessing three or more weights, instead of the two weights 142-143.
  • Inertial mass 138 is representative of one or more inertial masses, and the scope of this disclosure includes embodiments possessing two or more inertial masses instead of the single inertial mass 138.
  • Connector 135-136 is representative of one or more connectors, and the scope of this disclosure includes embodiments possessing two or more connectors instead of the single connector 135-136.
  • the scope of this disclosure includes
  • one or more of the at least one connector 135-136 is connected to, and/or attached to any portion, part, and/or surface of inertial mass 138.
  • Another embodiment does not possess a generator 133, e.g. and uses the kinetic energy of inertial mass 138 for a different useful purpose.
  • Pulley 132 is representative of one or more pulleys, and the scope of this disclosure includes embodiments possessing two or more pulleys, over which passes one or more connectors 135-136 each, instead of the single pulley 132.
  • Generator 133 is representative of one or more generators, and the scope of this disclosure includes embodiments possessing two or more generators instead of the single generator 133.
  • Flotation module 131 is representative of one or more flotation modules operably interconnected with one or more inertial masses 138 and/or one or more weights 142-143, and the scope of this disclosure includes embodiments possessing two or more flotation modules instead of the single flotation module 131.
  • Inertial mass 138 is representative of an inertial mass that is buoyant, neutrally-buoyant, or negatively buoyant, and/or characterized by any degree of buoyancy.
  • the scope of this disclosure includes embodiments possessing inertial masses of any degree of positive, negative, or neutral buoyancy.
  • FIG. 113 illustrates an embodiment of the current disclosure identical to the embodiment illustrated in FIG. 112. However, FIG. 113 illustrates the configuration and/or state of the embodiment approximately characteristic of the embodiment's passage through the wave trough, when the movement of the inertial mass is no longer constrained by connectors 161-162, i.e. those connectors are slack, and the movement of inertial mass 159 is limited only by connector 155-156, and the opposing forces imparted to inertial mass 159 therethrough by restoring weight 158.
  • the embodiment's inertial mass 159 is moving away from flotation module 151.
  • Connector 155-156, and attached weight 158 are moved in concert with the downward movement of the inertial mass 159.
  • pulley 152, and its operably connected generator 153 are able to extract electrical energy from the inertial mass' kinetic energy.
  • generator 153 As generator 153 generates electrical power, it also exerts an inhibiting or resistive torque on pulley 152 that resists the pull of inertial mass 159 on connector 155. This relatively upward force imparted to inertial mass 159 by pulley 152 through flexible connector 155 provides an upward acceleration to the inertial mass.
  • the embodiment's ability to systematically extract energy from ocean waves depends upon its ability to "reset” after it has “launched” its inertial mass downward, and extracted power from its downward movement. At some point, and in part as a result of the resistance of the opposing torque imparted to pulley 152 by generator 153, which in turn applies a counter-force to connector 155 as it moves over the pulley 152 under the influence of the downward moving inertial mass 159, the descent of inertial mass 159, relative to flotation module 151, slows, stops, and reverses. The inertial mass 159 begins to move upward relative to flotation module 151.
  • This upward movement may be the result of any and/or all of the following: 1) the upward force applied to inertial mass 159 by connector 155 and attached restoring weight 158; and 2) an upward force manifested by any degree of positive buoyancy in inertial mass 159.
  • FIG. 114 illustrates an embodiment of the current disclosure.
  • a flotation module 271 floats adjacent to the surface 270 of a body of water.
  • a pair of weights 282- 283 are suspended beneath flotation module 271 by flexible connectors 276-277.
  • Inertial mass 279 is suspended above weights 282-283 by flexible connectors 280-281.
  • inertial mass 279 is operably connected to restoring weight 278 by connector 274-275, which passes over, and/or through, pulley 272, which is operably and/or rotatably connected to generator 273.
  • inertial mass 279 As the embodiment accelerates downward into the water, e.g. as when floating on a wave of which the crest is passing and the midway point between the crest and the following trough is approaching, inertial mass 279 is fully raised above weights 282-283 and accelerates downward in tandem with the weights.
  • flotation module 271 and the weights 282-283 accelerate upward e.g. as when floating on a wave of which the trough is approaching
  • inertial mass 279 will tend to continue moving downward and will not manifest the same degree of upward acceleration.
  • This differential rate of upward acceleration will result in an increase in the distance between the inertial mass 279 and the flotation module 271. This will result in an paying out or lengthening of connector segment 274, causing pulley 272 to be turned, causing the generator 273 to generate electrical power.
  • each of 282 and 283 is a single suspended weight.
  • each of 282 and 283 can be two, three, four, or more than four suspended weights interconnected by intervening flexible or rigid connectors.
  • the two connectors attached to each suspended weight are attached to the suspended weight at opposite ends of the suspended weight.
  • the connectors attached to each suspended weight can be attached to the same point on the suspended weight, or to different points on the suspended weight.
  • the suspended weights are connected to the flotation module toward the periphery of the flotation module. In other embodiments the suspended weights can be connected to the flotation module at any location on the flotation module, directly or indirectly.
  • FIG. 114 is representative of a large number of related embodiments that may be derived from this representative embodiment.
  • Connectors 276-277 are representative of one or more connectors, and the scope of this disclosure includes embodiments possessing only one, or three or more connectors instead of the two connectors 276-277.
  • Connectors 280-281 are representative of one or more connectors connecting inertial mass 279 to weights 282-283, respectively, and the scope of this disclosure includes embodiments possessing any number of one or more connectors instead of the two connectors 282-283.
  • Weights 282-283 are representative of one or more weights, and the scope of this disclosure includes embodiments possessing only one, as well as those possessing three or more weights, instead of the two weights 282-283.
  • Inertial mass 279 is representative of one or more inertial masses, and the scope of this disclosure includes embodiments possessing two or more inertial masses instead of the single inertial mass 279.
  • Connector 274-275 is representative of one or more connectors, and the scope of this disclosure includes embodiments possessing two or more connectors instead of the single connector 274-275.
  • the scope of this disclosure includes
  • one or more of the at least one connector 274-275 is connected to, and/or attached to any portion, part, and/or surface of inertial mass 279.
  • Pulley 272 is representative of one or more pulleys, and the scope of this disclosure includes embodiments possessing two or more pulleys, over which passes one or more connectors 274-275 each, instead of the single pulley 272.
  • Generator 273 is representative of one or more generators, and the scope of this disclosure includes embodiments possessing two or more generators instead of the single generator 273.
  • Weight 278 is representative of one or more weights, and the scope of this disclosure includes embodiments possessing two or more weights instead of the single weight 278.
  • Flotation module 271 is representative of one or more flotation modules operably interconnected with one or more inertial masses 279 and/or one or more weights 282-283, and the scope of this disclosure includes embodiments possessing two or more flotation modules instead of the single flotation module 271.
  • Inertial mass 279 is representative of an inertial mass that is buoyant, neutrally-buoyant, or negatively buoyant, and/or characterized by any degree of buoyancy.
  • the scope of this disclosure includes embodiments possessing inertial masses of any degree of positive, negative, or neutral buoyancy.
  • FIG. 115 illustrates an embodiment of the current disclosure identical to the embodiment illustrated in FIG. 114. However, FIG. 115 illustrates the configuration and/or state of the embodiment after flotation module 291 and the weights 302-303 have begun to accelerate upward, e.g. have begun slowing their descent as the embodiment approaches a wave trough, while inertial mass 299 has continued downward, without an equal degree of upward acceleration, due to its inertia and momentum.
  • connectors 300-301 are slack and the vertical position, speed, and/or acceleration of inertial mass 299 is no longer significantly influenced by those connectors. Also note, that due to the energetic descent of inertial mass 299 relative to flotation module 291, connector segment 294 causes pulley 292 to rotate which causes generator 293 to generate electrical power.
  • weights 302-303 each of which is connected to the flotation module 291 and the inertial mass 299 at opposite ends of said weight, allows the upward movement of inertial mass 299 to be stopped and/or arrested relatively "gently" as the imposition of the opposing force of each weight, 302 and 303, is applied progressively as the weight is raised from an approximately vertical orientation to an approximately horizontal orientation.
  • FIG. 116 illustrates an embodiment of the current disclosure.
  • FIG. 116 is similar to the one illustrated and discussed in relation to FIG. 115. However, the embodiment illustrated in FIG. 116 includes two weights 323-324 instead of the single weight 283 illustrated in FIG. 115.
  • the behavior of the embodiment illustrated in FIG. 116 is substantially similar to the behavior of the embodiment illustrated and discussed in relation to FIG. 115.
  • the features and discussion that are, and/or would be, redundant with respect to other embodiments discussed elsewhere will not be repeated here, but is nonetheless still relevant and is included within the scope of the present disclosure.
  • weights 323 and 324 are connected by a flexible connector 325. In another embodiment, they are connected by a rigid connector.
  • FIG. 116 is representative of a large number of related embodiments that may be derived from this representative embodiment.
  • Weights 323-324 is representative of one or more weights, and the scope of this disclosure includes embodiments possessing one or more weights instead of the pair of weights 323-324.
  • Inter-weight connector 325 is representative of one or more flexible connectors, rigid connectors, and/or any other means, device, structural member, element, and/or construction, which connects and/or attaches one or more weights, represented by weights 323-324.
  • FIG. 117 illustrates an embodiment of the current disclosure.
  • FIG. 117 is similar to the one illustrated and discussed in relation to FIG. 116. However, the embodiment illustrated in FIG. 117 includes two weights 343-344 instead of the single weight 303 illustrated in FIG. 115. The behavior of the embodiment illustrated in FIG. 117 is substantially similar to the behavior of the embodiment illustrated and discussed in relation to FIG. 115. In one embodiment, weights 343 and 344 are connected by a flexible connector 345. In
  • FIG. 118 shows a vertical profile view of a stylized feature of the current disclosure.
  • Pulley/sheave/drum 118-3 is shown in profile with flexible connector 118-4 passing up, over, and back down drum 118-3.
  • Flexible connector 118-4 can be a wire, rope, cable, or any number of other linear tensile members.
  • Drum 118-3 can have a groove (following a helical pattern on the drum surface about the cylindrical axis) in which flexible connector 118-4 can interface.
  • the diameter (D) of drum 118-3 is at least 50 times the diameter (d) of flexible connector 118-4, i.e. it has a "D/d" ratio of at least 50. This ensures that flexible connector 118-4 is not excessively bent around drum 118- 3 in a way that would damage, fatigue, or otherwise impart damage to the components comprising flexible connector 118-4.
  • the flexible connector passes multiple times around the drum (not shown).
  • FIG. 119 shows a perspective view of FIG 118.
  • Sixteen subconnectors of flexible connector 119-4 are shown passing up, around, and over drum 119-3. These 16 subconnectors can comprise a ribbon-like flexible connector element as described in other figures.
  • the 16 subconnectors of flexible connector 119-4 can each pass over drum 119-3 once as shown in this figure (e.g. used to form one half of a traction winch as shown in FIG. 95).
  • the multiple instances of flexible connector 119-4 can also each pass over and wrap several times around drum 119-3 (e.g.
  • each flexible connector instance rigidly fixing itself to the surface of drum 119-3 (e.g. as shown in FIG 122 and 123).
  • FIG. 120 shows a perspective view of a preferred feature of the current disclosure. This preferred feature is similar to the feature described in FIG 118 and 119, except now drum 120-3 has a diameter twice as great as the drum illustrated in FIGS. 118 and 119. And, drum 120-3 supports only 4 subconnectors, unlike the 16 subconnectors supported by drum 119-3. However, the subconnectors supported by drum
  • FIGS. 118-121 illustrate the potential utility of satisfying a "D/d" ratio of 50 (or more) by utilizing a greater number of thinner cables rather than a few relatively thick cables, since the utilization of the thicker cables may require the use of rollers, pulleys, etc., of an inconveniently great diameter.
  • the use of a single cable with a diameter of 10 cm will require the use of a pulley or roller with a diameter of 50 m, if a D/d ratio of 50 is to be achieved.
  • this smaller diameter pulley or roller will have a longitudinal length of at least 100 cm (i.e., lateral space sufficient for 100 cables of 1 cm diameter each), whereas the 50-meter pulley or roller will have required no more than a 10 cm width.
  • FIG. 121 shows a vertical profile view of FIG 120. This figure illustrates the relative diameter of flexible connectors 121-4 passing around drum 121-3.
  • the diameter of drum 121-3 should be at least 50 times larger than the diameter of flexible connectors
  • FIG. 122 shows a top-down perspective on an embodiment of the present disclosure.
  • a buoy 550 has a central aperture 551 through which a plurality of cables pass into the body of water on which the buoy floats.
  • a parallel array, or "ribbon,” of cables, e.g. 553-554, are wound about a roller 552.
  • One end, e.g. 553, of each cable in the array is affixed to the roller 552.
  • the other end of each cable in the ribbon is connected to a submerged inertial mass (below the buoy and not visible from the illustrated perspective).
  • Another cable 555-556 is wound about the same roller 552.
  • One end 555 of that cable is likewise affixed to the roller 552.
  • the other end of that cable is connected to a submerged restoring weight (below the buoy and not visible from the illustrated perspective).
  • the buoy When the buoy falls in response to an approaching wave trough, it begins approaching (rather than moving away from) its inertial mass, and, because of this, the ribbon cable is now too long and becomes slacker, at least to a degree. At this time, the raised restoring weight causes the roller to reverse and rotate in the opposite direction, thereby rewinding onto itself the slack ribbon cable 554, and paying out the cable 556 to which the restoring weight is connected.
  • FIG. 123 shows a side view of the same embodiment illustrated and discussed in relation to FIG. 122.
  • Buoy 550 floats adjacent to a surface 551 of a body of water.
  • Ribbon cable 553/559 connects the embodiment's roller 552 to the submerged inertial mass 563.
  • the ribbon cable 553/559 is connected to the inertial mass 563 by means of a ribbon junction bar 561 and cable 562. Ribbon cable connects the inertial mass 563 to the roller 552 by passing through aperture 551 in the buoy 550.
  • Cable 555 connects the roller 552 to restoring weight 560. Cable 555 also passes through aperture 551 in order to connect the roller to the restoring weight. Cable 555 is wound around roller 552 in the opposite direction that characterizes the winding of ribbon cable 553/559 around the roller. So, when the ribbon cable shortens (as when the ribbon cable is slack and the buoy is approaching the inertial mass), the restoring weight's cable lengthens. And, when the ribbon cable lengthens (as when the buoy rises and pulls away from the inertial mass), the restoring weight's cable shortens, thereby raising the restoring weight and imparting to it gravitational potential energy.
  • Generators at each side of the roller are rotatably connected to its shaft and generate electrical power when the roller rotates, at least when it rotates in the direction that lengthens the ribbon cable segment 553/559 which occurs when the inertial mass pulls on that cable with substantial force thereby imparting substantial torque to the roller 552.
  • FIG. 124 illustrates a possible configuration and/or geometry of a ribbon cable 800.
  • the ribbon cable is characterized by a flat and/or a rectangular shape.
  • its connection to a ribbon junction bar 801 facilitates its connection to an inertial mass, e.g. by a cable 802.
  • the upper end of the ribbon cable might pass over a roller and/or be connected to a restoring weight or a roller.
  • Located on the ribbon junction bar 801 is at least one sacrificial anode (not shown) and the sacrificial anode is electrically connected to the constituent subconnectors of the ribbon through the ribbon junction bar 801 to protect them from corrosion.
  • FIG. 125 illustrates a possible configuration and/or geometry of a pair of connected ribbon cables 810 and 811.
  • These ribbon cables have approximately flat rectangular geometries at their upper ends 810 and 811. But their lower ends 812 and 813 are "bunched together” so as to morph the flat geometry of the top into an approximately tubular geometry at the bottom.
  • the tubular collections of the cables of which the ribbons are composed are held together at bindings 814 and 815 which are connected to individual cables 816 and 817, which are in turn joined and/or bound together at connector 818. That connector 818 is connected to cable 819 which might then be connected and/or attached to an inertial mass.
  • FIG. 126 illustrates a possible configuration and/or geometry of four interconnected ribbon cables 833-836. These ribbon cables have approximately flat rectangular geometries at their upper ends 833-836. But their lower ends merge to form and geometry that is approximately that of a square tube. The bottoms of the cables are connected to a square ribbon junction bar 831 which is in turn connected to a single cable 832 which might be connected to an inertial mass. And, the upper ends of the constituent ribbon cables might pass over rollers and/or be connected to restoring weights or rollers. [00440] FIG.
  • 127 illustrates a possible configuration and/or geometry of a ribbon cable 841.
  • the ribbon cable is approximately cylindrical and at its upper end 840 the ends of the cables are arrayed in an approximately circular pattern.
  • the tubular geometry continues down to the point at which the individual and/or constituent cables in the ribbon are connected to a circular ribbon junction bar 843.
  • the junction bar is connected, via structure 844, to a single cable 845, which might then be connected to an inertial mass.
  • the upper ends of the constituent cables might pass over pulleys and/or rollers and/or be connected to restoring weights or rollers.
  • FIG. 128 illustrates a possible configuration and/or geometry of four interconnected ribbon cables 850-853. These ribbon cables have approximately flat rectangular geometries across their entire lengths. And the ribbon cables remain separate, and are attached at different portions of a square ribbon junction bar 854. That junction bar is then connected to a single cable 857 and connector 856 by a pyramidal set of cables. An inertial mass might be connected to cable 857. And, the upper ends of the constituent ribbon cables might pass over rollers and/or be connected to restoring weights or rollers.
  • FIG. 129 illustrates a potential disadvantage of connecting a buoy to a submerged inertial mass by a pair of laterally separated vertical cables.
  • the device configuration on the left side of FIG. 129 illustrates a buoy 1290 at rest at the surface 1291 of a body of water.
  • Two vertical cables 1298-1299 connect the buoy to a submerged inertial mass 1292.
  • the upper ends of the cables are connected to the buoy at points 1293 and 1295.
  • the lower ends of the cables are connected to the inertial mass at points 1296 and 1297.
  • the cable 1307 wants to be excessively paid out by a distance of 1306.
  • the depth of the end of the buoy adjacent to 1303 increases, thereby imparting to cable 1307 a substantial upward force on the inertial mass at point 1305.
  • the force imparted to the inertial mass 1313 at point 1305 by cable 1307 is directed along the dashed line descending from point 1305. This force is applied to inertial mass at an approximate distance of 1311 from its center of gravity 1314.
  • This off-center force imparts to inertial mass 1313 a torque 1312 which will tend to impart a rotation to the inertial mass, thereby reducing its stability.
  • Such a rotation is not helpful to the behavior of a point- absorbing wave energy device that extracts power from heave- induced vertical motions of its buoy.
  • FIG. 130 illustrates an alternative to the cable geometry used to connect the buoy in FIG. 129 to its inertial mass.
  • an alternate device configuration to the one illustrated and discussed in relation to FIG. 129.
  • the alternate device configuration on the left side of FIG. 130 illustrates a buoy 1400 at rest at the surface 1401 of a body of water.
  • Two cables are connected to buoy 1400 at the same relative points at which the two vertical cables of the device configuration illustrated in FIG. 129 are connected to that buoy.
  • these lower ends of the two cables 1403-1404 in FIG. 130 are interconnected at a common connector 1407 or junction.
  • Two cables 1405 and 1407 connect the inertial mass 1402 to that same common connector 1407, and are in turn connected to the inertial mass at the same relative points as are the vertical cables of FIG. 129.
  • the inertial mass inhibits the ability of the common connector 1426 to rise in order to accommodate the raising of connection point 1423. Because of this disparity, the cable 1427 wants to be excessively paid out by a distance of 1425. However, due to its fixed length, the depth of the end of the buoy adjacent to 1424 increases, thereby imparting to cable 1427 a substantial upward force on the common connector 1426, and therethrough to the inertial mass 1422.
  • FIG. 131 shows a top-down view of an embodiment of the present disclosure.
  • a buoy 500 floats adjacent to a surface of a body of water.
  • the buoy 500 contains a central aperture 502.
  • a submerged end of ribbon cable 503/512 is connected to a submerged inertial mass (not visible) below the buoy.
  • the ribbon cable passes from the inertial mass through the aperture and onto and around a three -roller traction winch.
  • the traction winch's three rollers 504-506 are arranged in an approximately pyramidal or triangular arrangement, with two rollers 504-506 being positioned near and adjacent to an upper surface of the buoy 500.
  • a third roller 505 is positioned above the lower two and approximately between them.
  • Each strand of the ribbon cable is wound around the three cooperating rollers of the traction winch multiple times thereby creating sufficient friction with the rolling surfaces of the rollers to permit the cable's movement to engage and turn the rollers, even when the embodiment' s power-take-off (PTO) 507 resists the turning of the traction winch's rollers.
  • PTO power-take-off
  • each strand of the ribbon cable travels onto and around a roller 510 from which the ribbon cable is paid out in response to each increase in the separation of the buoy from the inertial mass, and, when driven by "rewinding motor” 511, onto which the ribbon cable is rewound in response to each decrease in the separation of the buoy from the inertial mass.
  • a rotary encoder 508 provides the control system with an indirect indication of the distance by which the buoy and the inertial mass are separated, and the length of the ribbon cable that connects the two.
  • FIG. 132 is a cross-sectional view of the embodiment of the present disclosure illustrated and discussed in relation to FIG. 131, and taken across section line 23 in FIG. 131.
  • Buoy 500 floats adjacent to a surface 501 of a body of water. Buoy 500 is connected to a submerged inertial mass 513 by a ribbon cable 514 (shown from the side). One end of the ribbon cable is connected to the inertial mass 513, from which it travels upward and passes through an aperture or channel 502 in the buoy. The strands of the ribbon cable 512 are then wound 515-517 around the three rollers 504-506 of a traction winch after which they travel to, and are wound 509 around, a roller 510 onto which the cable may be wound through the turning of the roller by "rewinding motor" 511.
  • FIG. 133 shows a top-down view of an embodiment of the present disclosure.
  • a buoy 600 floats adjacent to a surface of a body of water.
  • the buoy 600 contains four apertures 602-605. Adjacent to each aperture is a roller 606-609, respectively.
  • the shaft of each roller is rotatably connected on one side to a generator, e.g., 612 and 614, and, on the other side, to a "rewinding motor,” e.g., 613 and 615.
  • each roller Around each roller are wound the strands of four aperture- specific ribbon cables, e.g. 611. One end of each ribbon cable strand is affixed to the roller about which it is wound. The other end of each ribbon cable strand is connected to an inertial mass (not visible).
  • FIG. 134 shows a cross-sectional view of the embodiment of the present disclosure illustrated and discussed in relation to FIG. 133, and taken across section line 29 in FIG. 133.
  • Buoy 600 floats adjacent to a surface 601 of a body of water.
  • Rotatably mounted to an upper surface of the buoy are four rollers, e.g. 606-608.
  • wound about each roller are the strands of a roller- specific ribbon cable, e.g. 610 and 623.
  • One end of each ribbon cable strand is affixed to its respective roller.
  • the other end of each ribbon cable strand is affixed to a "ribbon junction bar," e.g., 617, 621, and 624.
  • Each ribbon junction bar is connected by a cable, e.g. 622, to an inertial mass 616.
  • Each ribbon cable e.g., 610, connects the inertial mass 616 to a roller, e.g., 606, on the buoy 600, passing through a ribbon-specific aperture, e.g. 602, in order to do so.
  • FIG. 135 shows a perspective view of an embodiment of the current disclosure.
  • a buoy 100, flotation module, floating platform, and/or buoyant object floats adjacent to the surface 101 of a body of water.
  • Attached to, mounted on, and/or incorporated within, the buoy 100 is a power take-off (PTO) 102, and/or electrical power-generation assembly.
  • PTO power take-off
  • a flat and/or ribbon cable 104 connects the PTO to a submerged inertial mass 105, traveling vertically through an aperture 103 in the buoy.
  • the inertial mass 105 resists that motion, thereby causing the ribbon cable 104 to move over, around, and/or relative to, the gears, pulleys, drums, and/or cable-engagement components, of the PTO 102, thereby generating electrical power.
  • At least a portion of the electrical power generated by the PTO 102 is stored within batteries 109, capacitors chemical fuel (e.g. hydrogen) generators and storage mechanisms, and/or other energy storage mechanisms, systems, assemblies, and/or components.
  • the buoy 100 Also attached to, mounted on, and/or incorporated within, the buoy 100 is at least one chamber 106, module, and/or container, in which are affixed a plurality of computing devices.
  • the computing devices therein are powered and/or energized at least in part by electrical energy provided and/or supplied by batteries 109.
  • Heat generated by the computing devices within computing module 106 is dissipated, at least in part, across the surfaces of fins 107 attached to the top of the computing module 106A, thereby warming the air above the buoy 100, and, at least in part, across the surfaces of fins 108 attached to the bottom of the computing module 106B, thereby warming the water below the buoy 100.
  • the illustrated embodiment 100 receives tasks, programs, data, messages, signals, information, and/or digital values, emitted 112, issues, and/or transmitted, from at least one satellite 111, at least in part, through antenna 110, the data having, at least in part, originated from a remote computer and/or server.
  • the illustrated embodiment 100 transmits 113, communicates, emits, and/or issues, data, task results, messages, signals, information, status updates, and/or digital values, at least in part, from antenna 110, which are subsequently received, at least in part, by satellite 111, which may then transmit that received data to a remote computer and/or server.
  • FIG. 136 shows a top-down view of the same embodiment of the current disclosure illustrated in FIG. 135.
  • a buoy 100 floats adjacent to the surface of a body of water. Attached to, mounted on, and/or incorporated within, the buoy 100 is a power take-off (PTO) 102, and/or electrical power-generation assembly.
  • the PTO includes at least two pulleys and/or rollers 102A and 102B, about which a ribbon cable 102C passes and/or rolls.
  • the ribbon cable 102C connects the PTO to a submerged inertial mass, traveling vertically through an aperture 103 in the buoy.
  • At least a portion of the electrical power generated by the PTO 102 is stored in an enclosed bank 109, assembly, and/or set of batteries, capacitors, chemical fuel (e.g. hydrogen) generators and storage mechanisms, and/or other energy storage mechanisms.
  • a plurality of computers, computing devices, network connectors, and/or computing resources are stored within chamber 106A, enclosure, module, and/or container, mounted on, embedded and/or incorporated within the buoy 100.
  • Affixed to the top of the computing module 106 A are heat-dissipating and/or cooling fins 107 that facilitate the transfer of heat generated by the computing resources within the computing module 106 A to the air above the buoy.
  • An antenna 110 receives data transmitted by a satellite, and transmits data to a satellite. In some embodiments, antenna 110 transmits data to, and receives data from, other similar devices.
  • FIG. 137 shows a side view of the same embodiment of the current disclosure illustrated in FIGS. 135 and 136, and taken along a section plane "2" specified in FIG. 136.
  • a buoy 100 floats adjacent to the surface 101 of a body of water. Attached to, mounted on, and/or incorporated within, the buoy 100 is a power take-off (PTO) 102, and/or electrical power-generation assembly.
  • the PTO includes at least two pulleys and/or rollers 102A and 102B, about which a ribbon cable 102C passes and/or rolls.
  • the ribbon cable 102C/104 connects the PTO to a submerged inertial mass 105, traveling vertically through an aperture 103 in and through the buoy.
  • a plurality of computers 114/115, computing devices, network connectors, and/or computing resources, are stored within chamber 106, enclosure, module, and/or container, mounted on, embedded and/or incorporated within the buoy 100.
  • computing resources and/or computers are affixed within two vertical banks 116 and 117 and/or arrays. As they operate, and consume electrical power, they generate heat which gives rise to convective currents, e.g. 118, within the computing module 106 and/or chamber. The convective currents carry heat from the computing devices and/or circuits to upper 107 and lower 108 fins.
  • Affixed to the top of the computing module 106 are heat-dissipating and/or cooling fins 107 that facilitate the transfer 120 of heat generated by the computing resources within the computing module 106 to the air above the buoy.
  • Affixed to the bottom of the computing module 106 are heat-dissipating and/or cooling fins 108 that facilitate the transfer 119 of heat generated by the computing resources within the computing module 106 to the water below the buoy.
  • the fluid within the computing chamber 106 is air. In some embodiments, the fluid within the computing chamber 106 is a liquid that does not conduct electricity to a significant degree. In some embodiments, the material within the computing chamber 106 that surrounds the computing circuits 116 and 117 is a phase- changing material that does not conduct electricity to a significant degree.
  • FIG. 138 shows a perspective view of an embodiment of the present disclosure. This embodiment is substantially similar to that of FIG. 55, except that an end of depending connector 3-150, i.e. an end of depending connector segment 3- 150b, i.e. end 3-160, does not hang freely in the body of water, but rather depending connector 3- 150/19-150 is wound around pulley/capstan 19-125 and can be attached to
  • FIG. 139 shows a perspective view of an embodiment of the current disclosure.
  • a buoy 130, flotation module, floating platform, vessel, raft, and/or buoyant object floats adjacent to the surface 131 of a body of water.
  • PTOs power take-offs
  • electrical power-generation assemblies Attached to, mounted on, and/or incorporated within, the buoy 130.
  • PTO-specific cables e.g. 133, chains, ropes, linkages, and/or flexible connectors, connect each respective PTO to the approximate center of a submerged inertial mass 134.
  • the cables pass through a hole 135 and/or aperture in a top surface of the inertial mass 134.
  • the buoy 130 Mounted on and/or in, attached and/or affixed to, and/or incorporated within, the buoy 130 are two "computing chambers and/or modules" 136 and 137. These are sealed, waterproof chambers inside of which are mounted and/or affixed computing circuits, computing devices, and/or computing resources and/or networks.
  • the computing circuits are energized directly and/or indirectly by electrical power generated by the embodiment's PTOs in response to wave action.
  • Thermally-conductive fins e.g. 138 and 139, are affixed to top surfaces of the computing chambers 136 and 137. These fins expedite the transfer of heat, generated by computers within the computing chambers, to the air above and/or around the embodiment.
  • the illustrated embodiment 130 contains and/or incorporates a keel 141, with a weighted end 142, that enhances and/or promotes the stability of the device.
  • the embodiment 130 also incorporates a rigid sail 140 that is able to impart thrust to the device when driven by wind. The amount of thrust being adjustable and/or able to be optimized through the rotation of the sail to an optimal angle with respect to the wind direction.
  • a rudder 143 allows the device's control system (e.g. one or more computers that control the behavior of the device) to steer the embodiment when it is moved in response to wind passing over its rigid sail 140.
  • An antenna 144 mounted on, and/or affixed to, the top of the rigid sail 140 allows the device to send and receive electronic, and/or electromagnetic, transmissions, preferably encrypted.
  • this antenna exchanges digital data with a satellite through which the device can exchange data, programs, instructions, status information, and/or other digital values, with a remote computer and/or server.
  • this antenna exchanges digital data with other similar devices, e.g.
  • FIG. 140 shows a top-down view of the same embodiment of the current disclosure that is illustrated in FIG. 139.
  • a buoy 130 floats adjacent to the surface of a body of water. Attached to, mounted on, and/or incorporated within, the buoy 130 is a plurality of power take-offs (PTOs), e.g. 132, and/or electrical power-generation assemblies.
  • PTOs power take-offs
  • PTO-specific cables, e.g. 133 connect each respective PTO to the approximate center of a submerged inertial mass 134.
  • the buoy 130 Mounted on and/or in, attached and/or affixed to, and/or incorporated within, the buoy 130 are two "computing chambers and/or modules" 136 and 137. These are sealed, waterproof chambers inside of which are mounted and/or affixed computing circuits, computing devices, and/or computing resources and/or networks.
  • the computing circuits are energized directly and/or indirectly by electrical power generated by the embodiment's PTOs in response to wave action.
  • Thermally-conductive fins e.g. 138 and 139, are affixed to top surfaces of the computing chambers 136 and 137. These fins expedite the transfer of heat, generated by computers within the computing chambers, to the air above and/or around the embodiment.
  • the embodiment 130 incorporates a rigid sail 140 that is able to impart thrust to the device when driven by wind.
  • the amount of thrust being adjustable and/or able to be optimized through the rotation of the sail to an optimal angle with respect to the wind direction.
  • An antenna 144 mounted on, and/or affixed to, the top of the rigid sail 140 allows the device to send and receive electronic, and/or electromagnetic, transmissions (e.g. radio).
  • FIG. 141 shows a side view of an embodiment of the current disclosure.
  • a buoy 130 floats adjacent to the surface 131 of a body of water. Attached to, mounted on, and/or incorporated within, the buoy 130 is a plurality of power take-offs (PTOs), e.g. 132, and/or electrical power-generation assemblies.
  • PTO-specific cables e.g. 133, chains, ropes, linkages, and/or flexible connectors, connect each respective PTO to the approximate center of a submerged inertial mass 134.
  • the cables pass through a hole 135 and/or aperture in a top surface of the inertial mass 134 and connect to a mounting point located approximately at the inertial mass's 134 geometric center, which is also its center of mass.
  • the buoy 130 Mounted on and/or in, attached and/or affixed to, and/or incorporated within, the buoy 130 are two "computing chambers and/or modules" 136 and 137. These are sealed, waterproof chambers inside of which are mounted and/or affixed computing circuits, computing devices, and/or computing resources and/or networks.
  • the computing circuits are energized directly and/or indirectly by electrical power generated by the embodiment's PTOs in response to wave action.
  • Thermally-conductive fins e.g. 138 and 139, are affixed to top surfaces of the computing chambers 136 and 137. These fins expedite the transfer of heat, generated by computers within the computing chambers, to the air above and/or around the embodiment.
  • the illustrated embodiment 130 contains and/or incorporates a keel 141, with a weighted end 142, that enhances and/or promotes the stability of the device.
  • the embodiment 130 also incorporates a rigid sail 140 that is able to impart thrust to the device when driven by wind. The amount of thrust being adjustable and/or able to be optimized through the rotation of the sail to an optimal angle with respect to the wind direction.
  • a rudder 143 allows the device's control system (e.g. one or more computers that control the behavior of the device) to steer the embodiment when it is moved in response to wind passing over its rigid sail 140.
  • An antenna 144 mounted on, and/or affixed to, the top of the rigid sail 140 allows the device to send and receive electronic, and/or electromagnetic, transmissions, preferably encrypted.
  • this antenna exchanges digital data with a satellite through which the device can exchange data, programs, instructions, status information, and/or other digital values, with a remote computer and/or server.
  • this antenna exchanges digital data with other similar devices, e.g.
  • FIG. 142 shows a back and/or rear view of an embodiment of the current disclosure.
  • a buoy 130 floats adjacent to the surface of a body of water. Attached to, mounted on, and/or incorporated within, the buoy 130 is a plurality of power take-offs (PTOs), e.g. 132, and/or electrical power-generation assemblies.
  • PTO-specific cables e.g. 133, chains, ropes, linkages, and/or flexible connectors, connect each respective PTO to the approximate center of a submerged inertial mass 134. The cables pass through a hole 135 and/or aperture in a top surface of the inertial mass 134.
  • buoy 130 Mounted on and/or in, attached and/or affixed to, and/or incorporated within, the buoy 130 are two "computing chambers and/or modules," e.g. 136. These are sealed, waterproof chambers inside of which are mounted and/or affixed computing circuits, computing devices, and/or computing resources and/or networks. The computing circuits are energized directly and/or indirectly by electrical power generated by the buoy 130.
  • the illustrated embodiment 130 contains and/or incorporates a keel 141, with a weighted end 142, that enhances and/or promotes the stability of the device.
  • the embodiment 130 also incorporates a rigid sail 140 that is able to impart thrust to the device when driven by wind. The amount of thrust being adjustable and/or able to be optimized through the rotation of the sail to an optimal angle with respect to the wind direction.
  • a rudder 143 allows the device's control system (e.g. one or more computers that control the behavior of the device) to steer the embodiment when it is moved in response to wind passing over its rigid sail 140.
  • An antenna 144 mounted on, and/or affixed to, the top of the rigid sail 140 allows the device to send and receive electronic, and/or electromagnetic, transmissions, preferably encrypted.
  • this antenna exchanges digital data with a satellite through which the device can exchange data, programs, instructions, status information, and/or other digital values, with a remote computer and/or server.
  • this antenna exchanges digital data with other similar devices, e.g.
  • FIG. 143 shows a top-down view of an embodiment of the current disclosure.
  • a buoy 210 floats adjacent to an upper surface of a body of water.
  • One end of a multi- stranded, laterally-distributed, cable 212, chain, rope, and/or flexible connector (a "ribbon") passes downward through an aperture 211 in the buoy 210 where it is connected to a submerged inertial mass (not shown).
  • Each strand of the multi-stranded cable 212 is wound around a pair of drums 213-214, pulleys, and/or rotating capstans, which increases the frictional binding between the cable and the drum.
  • the other end of each strand of the multi- stranded cable 212 is affixed to drum 214.
  • the cable 212 rotates the drums 213-214 which causes a shaft of generator 215, and/or power take-off (PTO), to rotate as well, thereby generating electrical power.
  • PTO power take-off
  • a sealed and/or waterproof and/or water-tight "computational chamber and/or enclosure” 216 Within one end of buoy 210 is embedded a sealed and/or waterproof and/or water-tight "computational chamber and/or enclosure" 216.
  • Computational chamber 216 is attached to an upper surface of buoy 210 by a flange 219.
  • the walls, e.g. 216, of the computational chamber below the flange, and the corresponding and/or adjacent walls of the buoy, e.g. 217, are separated by a gap 218.
  • the computational chamber Within the space and/or gap, the computational chamber is surrounded by, and/or bathed in, a thermally-conductive fluid.
  • Heat-dissipating fins e.g.
  • Affixed to and/or within the computational chamber 216 is a plurality of computing devices, computing circuits, computers, and/or networked computers. At least some of those computing devices are energized, at least in part, with electrical power generated by the PTO 215. At least a portion of the heat generated by the computing devices within the computational chamber 216 is convectively transmitted to the thermally conductive upper wall of the chamber, and to the fins, e.g. 220, thereon, from which it is convectively transmitted and/or transferred to the air above the buoy.
  • a pair of ducted fans 221-222 mounted to an upper surface of the buoy 210 provide forward thrust with which the embodiment may propel itself across the surface of the water on which it floats.
  • the ducted fans consume a portion of the electrical power generated by the generator 215.
  • the buoy may propel itself in any direction, and/or to any specific location (e.g. to specific geospatial coordinates) on the surface of the body of water.
  • FIG. 144 shows a side view of the same embodiment of the current disclosure illustrated in FIG. 143, and taken along a section plane "11" specified in FIG. 143.
  • a buoy 210 floats adjacent to an upper surface 233 of a body of water.
  • One end of a multi- stranded, laterally-distributed, cable 212/225, chain, rope, and/or flexible connector passes downward through an aperture 211 in the buoy 210 where it is connected to a submerged inertial mass 226.
  • Each strand of the multi- stranded cable 212/225 is wound around a pair of drums 213-214, pulleys, and/or rotating capstans, which increases the frictional binding between the cable and the drum.
  • each strand of the multi- stranded cable 212 is affixed to drum 214.
  • the cable 212 rotates the drums 213-214 which causes a shaft of generator 215, and/or power take-off (PTO), to rotate as well, thereby generating electrical power.
  • PTO power take-off
  • Within one end of buoy 210 is embedded a sealed and/or waterproof and/or water-tight "computational chamber and/or enclosure" 216.
  • Computational chamber 216 is attached to an upper surface of buoy 210 by a flange 219. Those walls of the computational chamber 216 which are located below the flange 219, and the
  • a gap, space, and/or void 218 Within the space 218 and/or gap, the computational chamber 216 is surrounded by, and/or bathed in, a thermally-conductive fluid.
  • a thermally-conductive plate 227 and/or wall is affixed to an upper surface of a "ledge" 228 at the base of the aperture 218 and/or space containing the thermally-conductive fluid 218.
  • Heat-dissipating fins e.g. 220
  • Heat-dissipating fins are attached and/or affixed to an upper surface of the computational chamber 216 and facilitate and/or expedite the transfer 231 of the heat trapped within the chambers to the air above and/or around the buoy.
  • Heat- dissipating fins e.g. 230
  • the fins 230 allow heat conductively transmitted and/or transferred from the fluid 218 to the plate 227 to be more quickly and efficiently transmitted 232 and/or transferred to the water beneath the buoy.
  • Affixed to and/or within the computational chamber 216 is a plurality of computing devices, computing circuits, computers, and/or networked computers. At least some of those computing devices are energized, at least in part, with electrical power generated by the PTO 215. At least a portion of the heat generated by the computing devices within the computational chamber 216 is convectively transmitted to the thermally conductive upper wall of the chamber, and to the upper, e.g. 220, fins thereon, from which it is convectively transmitted and/or transferred to the air above the buoy.
  • At least a portion of the heat generated by the computing devices within the computational chamber 216 is convectively transmitted to the thermally conductive side and bottom walls of the chamber 216, and thereafter and/or therethrough to the heat- conductive fluid surrounding the chamber 216. At least a portion of the heat in the fluid 218 is transferred and/or transmitted to the plate 227, and thereafter and/or therethrough to lower fins, e.g. 230, thereon, from which it is convectively transmitted and/or transferred to the water below the buoy.
  • a pair of ducted fans e.g. 221 are mounted to an upper surface of the buoy 210 and provide forward thrust with which the embodiment may propel itself across the surface 233 of the water on which it floats.
  • the ducted fans consume a portion of the electrical power generated by the generator 215.
  • the buoy may propel itself in any direction, and/or to any specific location (e.g. to specific geospatial coordinates) on the surface of the body of water.
  • FIG. 145 shows a perspective view of an embodiment of the present disclosure.
  • the inertial mass 3117 is an open-topped ellipsoidal vessel.
  • the mass of the water trapped within the vessel causes the vessel to resist acceleration, while its positive net weight causes it to accelerate downward, and regain its nominal operational depth (and indeed develop a significant downward momentum), after that portion of a wave- and/or power-cycle in which it is accelerated upward.
  • FIG. 146 shows a perspective view of the inertial mass 3117 associated with the embodiment of the present disclosure that is illustrated in FIG. 145.
  • the "bullet- shaped" lower end of the ellipsoidal inertial mass minimizes the degree to which drag retards the descent of the inertial mass, allowing it to achieve a greater downward momentum during its descent, which downward momentum contributes to the efficacy of the power-generation stroke when the flotation module accelerates upward.
  • the inertial mass's open upper mouth 3118 facilitates the fabrication of the vessel, and reduces material costs, while not significantly diminishing the vessel's inertial properties.
  • the walls of the ellipsoidal inertial mass are curving "inward", toward its central longitudinal axis, in the region of the open upper “mouth.” This allows the cords 3119 to assume a more conformal configuration relative to the side walls at 3117.
  • the inertial mass 3117 is connected to flexible connector 3112 by a network (i.e., a "net") of cords 3119, although other means, methods, and/or structures, such as shackles, could be used to connect the inertial mass to the connector 3112.
  • a network i.e., a "net”
  • cords 3119 although other means, methods, and/or structures, such as shackles, could be used to connect the inertial mass to the connector 3112.
  • the ellipsoidal is not precisely an ellipsoid, but can be, e.g., a paraboloid.
  • FIG. 147 shows a perspective view of an embodiment of the present disclosure.
  • the inertial mass 3317 is composed of a bundle of laterally oriented pipes or tubes 3325.
  • the mass of the water trapped within the pipes, and between the pipes, causes the bundle 3317 to resist vertical acceleration, while its positive net weight causes it to accelerate downward, and regain its nominal operational depth, ideally with significant downward momentum, after that portion of a wave- and/or power-cycle in which it is accelerated upward.
  • the individual pipes are bound together into a bundle by circumferential bands 3317, and a flexible connector 3312 is connected to one such circumferential bands.
  • FIG. 148 shows a side view of the embodiment of FIG. 147.
  • FIG. 149 shows a side view, different from the one provided in FIG. 148, of the same embodiment of the present disclosure that is illustrated in FIGs. 147 and 148.
  • FIG. 150 shows a perspective view of an embodiment of the present disclosure. This embodiment is similar in most respects to the one illustrated and discussed in relation to FIGs. 147-149.
  • inertial mass 3625 is a single rigid structure 3625 that incorporates seven horizontally-oriented tubular channels and/or voids. These channels have cross-sectional shapes (with respect to section planes normal to their longitudinal axes) that are approximately hexagonal.
  • the structure 3625 is suspended beneath and/or by a beam 3627, which in turn is suspended by, and/or connected to, flexible connector 3612.
  • a beam 3627 which in turn is suspended by, and/or connected to, flexible connector 3612.
  • this embodiment has an "open-sided” inertial mass, allowing water to pass laterally through it, while being rigid and resisting vertical accelerations.
  • FIG. 151 shows a side view of the same embodiment.
  • Inertial mass 3625 is seen from a side perspective that provides a view orthogonal to the longitudinal axes of the constituent hexagonally- shaped channels within the inertial mass structure 3625.
  • the center of mass of inertial mass 3625 is approximately beneath point 3612B, e.g., the center of mass can be at 3625C.
  • the inertial mass can rotate in a horizontal plane around a vertical axis defined by the rigging point 3612B.
  • Inertial mass 3625 has a greater lateral width or extent to the right 3625 A of point 3625C than to the left 3625B of point 3625C.
  • inertial mass 3625 can respond like a weather vane when it is exposed to an ocean current.
  • the ocean current will tend to create a greater torque at 3625A than at 3625B, causing end 3625B to face into the current and end 3625A to face away from the current. This will tend to allow the current to pass more easily through the hexagonal "holes" in the inertial mass, allowing the converter as a whole to be less susceptible to currents.
  • inertial mass 3625 has a greater lateral cross section on one side 3625A of its attachment point 3612B than on an opposite side 3625B, and/or has a greater lateral cross section on one side 3625A of its center of mass 3625C than on an opposite side 3625B.
  • FIG. 152 shows a perspective view of another embodiment of the present disclosure. In this embodiment, a series and/or string of offset weights 4207 are attached to the bottom of inertial mass 4205.
  • the effective net weight of inertial mass 4205 is controlled and/or adjusted through the control and/or adjustment of the average depth of the inertial mass 4205.
  • the number of offset weights that are supported by the inertial mass 4205, instead of by the flotation module 4200, is adjusted through the control and/or modification of the depth of the inertial mass 4205. And, the more offset weights that are supported by the inertial mass 4205, the greater the effective net weight of the inertial mass 4205.
  • the inertial mass 4205 is slightly positively buoyant, having an average density lesser than the surrounding water.
  • inertial mass 4205 has a substantially neutral average density (i.e., the same density as that of the water that is displaces). With respect to this neutral-density embodiment, the more offset weights that are supported by the inertial mass 4205, the greater the effective net weight of the inertial mass 4205. [00523] And, in one embodiment, inertial mass 4205 has a greater average density than the water it displaces.
  • offset weights that are supported by the flotation module 4200 are in effect increasing the effective net weight of the restoring weight, which counters the net weight of the inertial mass 4205 with respect to the movement of the flexible connector 4202 / 4210 that connects them through the power-take-off 4215.
  • the effective net weight of the inertial mass 4205 is still increased in proportion to the number of offset weights directly supported by it.
  • the combined net weight of four offset weights 4207 A-D act to increase the effective net weight of inertial mass 4205. While the combined net weight of five offset weights 4207E-I act to increase the effective net weight of restoring weight 4209.
  • the inertial mass 4205 of embodiment 4200 is cylindrical, tall, and relatively narrow.
  • the inertial mass 4205 would be expected to operate at an average depth that would place it near, if not below, the wave base characteristic of the waves that lift, and let fall, the flotation module 4200 at the surface 4201 of the body of water on which it floats.
  • FIG. 153 shows a perspective view of the same embodiment of the present disclosure that is illustrated and discussed in relation to FIG. 152.
  • the configuration of the embodiment that is illustrated in FIG. 153 differs from the one illustrated and discussed in relation to FIG. 152, in that the average depth of the inertial mass 4205 has been decreased (i.e., the inertial mass has risen), and, concomitantly, the average depth of the restoring weight 4209 has been increased.
  • This change in the average depths of the inertial mass 4205 and the restoring weight 4209 has resulted in all nine of the offset weights 4207 A-I being suspended from, and adding to the effective net weight of, inertial mass 4205 (instead of just four of the offset weights as in the configuration illustrated in FIG. 152). [00528] Likewise, this change in the average depths of the inertial mass 4205 and the restoring weight 4209 has resulted in the effective net weight of the restoring weight 4209 not being augmented by any of the offset weights (instead of being augmented by five offset weights as in the configuration illustrated in FIG. 152). A change in the average depth of the inertial mass can be effectuated by varying the resistance or countertorque offered by generator 4214 or 4213.
  • FIG. 154 shows a perspective view of an embodiment of the present disclosure that is similar to the one illustrated and discussed in relation to FIGs. 152 and 153.
  • the string of offset weights that is present on the flexible connector 4208 that connects the restoring weight 4209 to the bottom of inertial mass 4205 in the embodiment illustrated in FIGs. 152 and 153 have been removed from that connector and transferred to a separate flexible connector 4415, one end of which is also connected to the bottom of inertial mass 4404, but the other end of which is connected to a winching mechanism 4417 and 4416 located on the flotation module 4400 adjacent to an aperture 4418 through which the flexible connector 4415 descends.
  • FIGs. 152 and 153 adjusts the effective net weight of its inertial mass by adjusting the average depth of its inertial mass and restoring weight.
  • the number of offset weights that contributes to the effective net weight of its inertial mass is directly correlated with the average depth of that inertial mass.
  • the embodiment illustrated in FIG. 154 adjusts the effective net weight of its inertial mass 4404 by adjusting the length of flexible connector and/or cable 4415.
  • the number of offset weights 4414 that contribute to the effective net weight of the inertial mass is directly controlled through the control of the length of connector 4415.
  • the embodiment illustrated in FIG. 154 allows the effective net weight of the inertial mass 4404 to be adjusted without adjusting or otherwise changing the average depth of the inertial mass 4404 and restoring weight 4407. Furthermore, the
  • FIG. 154 allows the effective net weight of the inertial mass 4404 to be adjusted without adjusting or otherwise changing the effective net weight of the restoring weight.
  • the adjustment and/or control of the effective net weight of the inertial mass 4404 has been decoupled from any related and/or consequential change in the effective net weight of the restoring weight 4407.
  • FIG. 155 shows an elevated perspective view of another embodiment of the current disclosure.
  • the inertial mass has been replaced by an inertial water trapping device 5201, which can, if desired, be referred to as an inertial mass or "quasi" inertial mass.
  • Inertial water trapping device 5201 performs the function of an inertial mass less well than most of the other inertial masses described above because it imparts a large degree of vorticity to the surrounding water as it moves through it. However, it does succeed in constraining the vertical movement of a large volume of water, and hence allows the inertia of that water to be exploited.
  • Inertial water trapping device 5201 consists of a series of horizontally oriented plates e.g., 5201B, 5201C, 5201D , arranged at vertical intervals.
  • the plates are separated by some vertical distance, this distance being typically (though not necessarily) less than a diameter (or other maximal horizontal dimension) of the plates.
  • the plates can all be of uniform size and shape, or they can be of different sizes and/or different shapes.
  • the plates can be circular, square, triangular, etc.
  • the plates need not be oriented exactly to the horizontal, but can be somewhat diagonal.
  • the plates are kept apart by spacing lines and/or spacing rods.
  • 5202B is a flexible spacing line.
  • 5202C is a rigid spacing rod.
  • inertial water trapping device In addition to, or in lieu of, vertical rigid spacing rods, diagonally oriented rigid spacing rods can be provided, giving the inertial water trapping device the form of a linear truss or an elongate space truss, wherein horizontal plates 5201B are placed at intervals within the framework provided by the truss. Typically, only spacing rods or only spacing lines will be used; the combination of the two is shown here only for illustration.
  • inertial water trapping device 5201 is, on average (including all the water contained in the convex hull of minimum volume around it), negatively buoyant, but perhaps only slightly so.
  • FIG. 156 shows a side view of the same embodiment shown in Figure 155.
  • FIG. 157 shows an inertial water trapping device like one of those described in the figure description to FIG. 155.
  • the inertial water trapping device has the form of a linear truss containing horizontal plates. Diagonal spacing rods 5203B have been provided for additional structural strength.
  • FIG. 158 shows a perspective view of an embodiment 720 of the current disclosure. This embodiment utilizes a stacked and/or vertically-aligned set of plates 732-735.
  • FIG. 159 shows a perspective view of an embodiment of the current disclosure.
  • Inertial mass 8-140 encloses, confines, and/or traps a large volume of water but need not have any rigid walls. It can be collapsible for manufacture, transportation, and the early stages of deployment. It can assume its full volume only upon final
  • Inertial mass 8-140 consists of two substantially frustoconical or conical parts: bottom section 8-180 and top section 8-185.
  • the top-view cross section of the inertial mass can be other than a circle. In some embodiments, it is a square. In some embodiments, it is a triangle. In some embodiments it is a polygon with any number of sides.
  • the analogs of the frustoconical sections, e.g. 8-185 are frustopyramidal.
  • Mouth spacer 8-195 depends from depending connector 8-150 by a plurality of top section tendons e.g. 8-186.
  • Mouth spacer 8-195 "holds apart” the vertical bottom section tendons e.g. 8-181 at their top portions and likewise “holds apart” the top section tendons e.g. 8-186 at their bottom portions, thereby defining an approximately circular mouth defining the larger base of each frustoconical section. Water can pass freely through the mouth spacer 8-195 in the vertical (i.e. axial) direction.
  • Mouth spacer 8-195 can be formed by a ring, as shown here, or by elongate beams crisscrossed, or by any other means of "holding apart” the relevant flexible walls and/or tendons so that they do not collapse inward under the inward component of the tension force created by inertial mass weighted portion 8-200.
  • a plurality of vertical bottom section tendons e.g. 8-181 depend from mouth spacer 8-195 and suspend inertial mass weighted portion 8-200.
  • Inertial mass weighted portion 8-200 can be made of concrete, steel, iron, or any other material with density greater than water.
  • the vertical bottom section tendons e.g. 8-181 and the top section tendons e.g. 8-186 can be the same tendons, i.e. one of these tendons can have one end connected at top ring 8-190, pass through and/or around mouth spacer 8-195, and have a second end connected at inertial mass weighted portion 8-200.
  • Inertial mass weighted portion 8-200 holds vertical bottom section tendons e.g. 8-181 in tension so that they are each substantially straight.
  • the vertical bottom section tendons e.g. 8-181 together define an approximately frustoconical shape.
  • the tendons e.g. 8-181 are attached to inertial mass weighted portion 8-200.
  • Flexible sheeting or fabric forms a substantially impermeable "skin", “surface”, or “wall” around the circumferential perimeter of the bottom section 8-180 and around the circumferential perimeter of the top section 8-185.
  • the flexible sheeting or fabric can be PVC fabric, nylon fabric, thin aluminum, thin plastic, or any other similar thin sheeting or fabric.
  • Preferably the flexible sheeting or fabric is collapsible, but this is not necessary.
  • the flexible sheeting or fabric can interface with the tendons directly (e.g. through weaving or stitching) so that the fabric/sheeting cannot be pulled apart from the tendons, or the flexible sheeting or fabric can merely rest against the inside of the tendons.
  • the flexible sheeting or fabric is substantially impermeable to water and allows the inertial mass to have a large "effective inertia" on account of the water effectively trapped inside it.
  • Horizontal bottom section rigid spacers e.g. 8-182 are provided to keep the structure open.
  • a top ring 8-190 or other similar means can be provided to define a top opening 8-191 which is not obstructed by fabric or sheeting.
  • top section 8-185 and the bottom portion of fabric walls of bottom section 8-180 have been made transparent in this figure for clarity of illustration.
  • FIG. 160 shows a side cross section of the inertial mass and part of the depending connector.
  • the lighter grey regions e.g. 8-185 and 8-180, are regions where a substantially impermeable skin, wall, or fabric is circumferentially disposed around the frustoconical section.
  • FIG. 161 shows a side view of an embodiment of the current disclosure. This embodiment is similar in most respects to the embodiment of FIG. 159. There are a few major differences.
  • top section 9-185 of inertial mass 9-140 there is no fabric or sheeting defining the top section 9-185 of inertial mass 9-140. Instead, the top section is "open,” consisting only of tendons e.g. 9-186 which suspend the parts of the inertial mass beneath them e.g. mouth spacer 9-195. Inertial mass 9-140 thus defines a "cup” or “ice cream cone” shape, with a substantially enclosed/sealed bottom portion but an open top portion. Such an inertial mass will substantially contain, confine, and enclose a significant volume of water in the manner required.
  • the inertial mass can have "effective mass” that includes the mass of the confined water.
  • the inertial mass can likewise have an “effective mass” that includes the mass of the water confined inside it, owing to the fact that the bottom portion of the inertial mass directly encloses said water.
  • the inertial mass has a small opening or openings at a bottom portion thereof, provided that such small opening or openings does/do not allow substantial amounts of water to pass in a vertical, i.e. axial, direction, i.e. provided that despite the opening or openings the bottom portion of the inertial mass nonetheless encloses and/or traps a large volume of water when accelerated upward.
  • restoring weight 9-160 is toroidal and
  • FIG. 162 shows a perspective view of an embodiment of the current disclosure. This embodiment is similar in most respects to the embodiment of FIG. 161. There are a few differences.
  • a plurality of pulleys/capstans e.g. 10-125, are operatively connected to a plurality of depending connectors, e.g. 10-150. Each of these depending connectors is operatively connected at one end to the inertial mass 10-140 and at one end to the restoring weight 10-160. Each depending connector can have its own aperture e.g. 10- 115. Each of the pulleys/capstans can interface to its own generator or can be
  • each pulley-capstan is associated with its own separate restoring weight, i.e. there are a plurality of restoring weights.
  • FIG. 163 shows a perspective view of an embodiment of the current disclosure.
  • top conical section 11-185 is significantly larger in the vertical dimension ("height") than its analogous frustoconical section 8-185 in FIG. 160.
  • Top conical section 11-185 can be the same height as, or a greater height than, bottom conical section 11-180.
  • Second, top conical section 11-185 has substantially impermeable walls, fabric, and/or sheeting over its entire outer circumferential surface. There is no "opening" at 11- 186.
  • the vertical tendons of bottom conical section 11-180 e.g. tendon 11- 181 join together at a common point 11-201 so that inertial mass weighted portion 11- 200 depends most immediately from a single connector 11-202 rather than from a plurality of tendons.
  • FIG. 164 shows a side cross section of the inertial mass 11-140 and part of the depending connector.
  • the lighter grey regions e.g. 11-185 and 11-180, are regions where a substantially impermeable skin, wall, or fabric is disposed around the conical section, e.g. circumferentially.
  • FIG. 165 shows a perspective view of an embodiment of the current disclosure.
  • the embodiment of this figure is similar in most respects to the embodiment of FIG. 163. However, in this embodiment, only the bottom conical section 12-180 has a circumferential shell, skin, fabric, and/or wall. The top conical section 12-185 is "open,” having no circumferential shell, skin, fabric and/or wall.
  • FIG. 166 shows a side cross section of the inertial mass 12-140 and part of the depending connector.
  • the lighter grey region 12-180 is the region where a substantially impermeable skin, wall, or fabric is disposed around the conical section, e.g.
  • FIG. 167 is an illustration of an embodiment of the current disclosure.
  • a flotation module 101 floats adjacent to the surface 100 of a body of water.
  • a submerged inertial mass 117 i.e. open-topped water-filled vessel
  • Joint 113 is operatively connected, via flexible connector 107, to gear 106 which rotates, in response to changes in the depth of the vessel 117 relative to flotation module 101, so as to lengthen flexible connector portion 107 and
  • the wave-induced raising of the surface 100 of the water coupled with the buoyancy of flotation module 101 causes a buoyant force that is sufficient to overcome the resistive torque of the generator.
  • the cycle continues, thus extracting energy from the rising side of every wave, and restoring the original device configuration during the falling toward every trough.
  • the buoyant force generated by flotation module 101 during its rise in response to approaching wave crests causes the generator to spin, thus generating electrical power. However, it also lifts the restoring mass above its "resting stop" (joint 113), and point of greatest relative depth, thus imparting gravitational potential energy to the restoring mass. That stored gravitational potential energy is then expended, at least in part, in the restoration of the original relative positions and/or orientations of the flexible connector 107 and the restoring and damping masses connected thereto.
  • FIG. 168 is an illustration of an embodiment of the current disclosure similar to the embodiment illustrated and discussed in FIG. 167.
  • a flotation module 201 floats adjacent to the surface 200 of a body of water.
  • a submerged inertial mass 217 (i.e. open-topped water-filled vessel) is suspended from a flexible connector 204 and 212.
  • a "stop" 211 is immovably connected to flexible connector 204 and 213, and establishes and/or defines the maximal relative depth to which a weight 207 can descend.
  • flotation module 201 moves down following the passage of a wave crest, it stops pulling up against the relatively immobile inertial mass 217, and restoring mass 207 falls thereby removing any slack in flexible connector portions 204 and/or 205. Vessel 217 falls under the influence of gravity too.
  • plunger 221 may fall quickly, owing its relatively lesser drag, and relatively higher net effective weight.
  • the faster falling of plunger 221 opens orifice 218, allowing water to enter the lowermost portion of the falling vessel, thereby relieving any reduction in pressure, and thus increasing the rate of the vessel's 217 falling.
  • Plunger 221 is attached and/or connected to spar 214 which is held in coaxial relation to the vessel 217 by a sleeve bearing in the center of strut 213 and 215.
  • plunger 221 is able to move up and down so as to close and open, respectively, orifice 218 at the bottom of the inertial mass 217.
  • FIG. 169 is a cross-sectional view taken along line AA in FIG. 168
  • the outer wall 300 of vessel 217 in FIG. 168 is circular.
  • Orifice 218 in FIG. 168 is illustrated herein as 302.
  • FIG. 170 is an illustration of an embodiment of the current disclosure similar to the embodiment illustrated and discussed in FIG. 168.
  • the weight 413 does not rise and fall approximately coaxially with the flexible connection that joins the inertial mass 419 to the gear 405.
  • the weight 413 is not terminally connected to the flexible connector 411, but instead utilizes a pulley wheel 412 that allows the flexible connector to lengthen and shorten while preserving weight 413's medial relation to gear 405 and flexible connector attachment point 407.
  • weight 413 rises and falls as well, with respect to its separation from flotation module 401.
  • the maximum relative depth and/or separation of weight 413 with respect to flotation module 401 is established, defined, and/or enforced, by flexible connector 408. Weight 413 cannot descend further than the extent permitted by connector 408.
  • the inertial mass 419 is open on its bottom 422 to the surrounding water 400. It is closed on all other sides, e.g. 419.
  • Supplemental weight 420 around the perimeter of the vessel's 419 base promotes its descent following its rising in response to the upward acceleration of flotation module 401.
  • Sliding uni-directional orifice 415 moves down when the inertial mass is being pulled upward by flotation module 401, thus preventing any influx of ambient water into the vessel's interior 421, and thereby maximizing the immobility of the vessel 419 by preserving any partial vacuum that develops within 421 the vessel.
  • Sliding uni-directional orifice 415 moves up, thereby allowing for the flow 417 of water from the vessel's interior 421 to the outside when flotation module 401 is descending, and thereby facilitating the restoration of the vessel's original, nominal depth.
  • FIG. 171 is a side view of the same embodiment illustrated in FIG. 170.
  • Flotation module 501 contains two generators 502-503. Each generator, e.g. 502, is rotatably connected to a shaft, e.g. 504, which is rotatably connected to a bevel gear assembly, e.g. 506. Each bevel gear assembly, e.g. 506, is rotatably connected to a shaft that is attached and/or connected to a gear 508, and each said shaft is positionally stabilized by a sleeve bearing, e.g. 507.
  • a sleeve bearing e.g. 507.
  • FIG. 172 is a perspective view of the sliding uni-directional orifice 415 illustrated and discussed in FIG. 170.
  • an orifice in vessel wall 604 allows water to pass 602 freely from one side of the wall to the other.
  • the cap at least partially obstructs the orifice thereby inhibiting or preventing the flow of water from one side of wall 604 to the other.
  • the cap is lifted and water is able to flow 602 from the inside of the vessel to the outside, thus relieving and/or diminishing any excess of pressure in the water inside the vessel.
  • FIG. 173 is an illustration of an embodiment of the current disclosure similar to the embodiment illustrated and discussed in FIG. 170.
  • FIG. 174 is a top-down perspective illustration of an embodiment of the current disclosure. This illustration shows the top of the embodiment's flotation module 800. Shown in dashed lines, indicating their presence some distance below the upper surface of the flotation module, is the relative size, orientation and/or position of the inertial mass 801, and the restoring float 802.
  • FIG. 175 is an illustration of a cross-sectional view of the embodiment of the current disclosure illustrated and discussed in FIG. 174 and taken along line CC in FIG. 174.
  • the embodiment illustrated here is similar to the one illustrated and discussed in FIG. 167.
  • the restoring mass illustrated in the embodiment of FIG. 167 is a weight, which achieves and/or manifests its restoring force through its positive net effective weight, and its tendency to sink
  • the restoring mass illustrated in this embodiment is a float 905, which achieves and/or manifests its restoring force through its negative (i.e. buoyant) net effective weight.
  • the restoring mass illustrated in this embodiment is a float 905, which achieves and/or manifests its restoring force through its negative (i.e. buoyant) net effective weight.
  • the flotation module 901 When at rest, the float 905 rests adjacent to the bottom of flotation module 901 near to the surface 900 of the body of water in which flotation module 901 floats. However, as flotation module 901 rises in response to an approaching wave, the submerged inertial mass 914 resists its upward acceleration creating a tension in the flexible connector 902. This tension results in the lengthening of connector portions 902 and 908, and the corresponding shortening of flexible connector portion 909. As flotation module 901 rises, and the inertial mass 914 resists that rising, the float 905 descends. If it descends to the point of abutting the inertial mass, then the separation between flotation module 901 and the submerged inertial mass 914 cannot increase further. At such a moment, and/or in such a circumstance, the flotation module may be submerged.
  • the float 905 As flotation module 901 descends, the float 905 is free to rise thus maintaining tension in the flexible connectors 902, 908 and 909. After the float 905 reaches the base of flotation module 901, and can rise no further, the inertial mass 914 is free to descend. Its flaps are free to open to allow ambient water to flow 918 into the inertial mass 914 which facilitates the flow of water out of the open top of the vessel without the creation of any regions of reduced pressure, which might impede the vessel's descent.
  • FIG. 176 is a bottom-up perspective illustration of a cross-sectional view of the embodiment of the current disclosure illustrated and discussed in FIGS. 174 and 175 and taken along line A A in FIG. 175.
  • the gear 1004 is operatively connected to the flexible connector 1002-1003.
  • the gear 1004 is positioned within a recessed area 1001 in the bottom of the buoy that allows the gear and its flexible connector to communicate with the body 900 of water upon which it floats.
  • FIG. 177 is a top-down perspective illustration of a cross-sectional view of the embodiment of the current disclosure illustrated and discussed in FIGS. 174-176 and taken along line BB in FIG. 175.
  • the inertial mass 1100 has supporting struts, e.g. 1101, upon and/or to which one end of flexible connector 902 is attached. Also attached is pulley 1104 about which the flexible connectors 908-909 are operatively connected. Flaps, e.g. 1102, which open inward, i.e. into the interior 1105 of the inertial mass 1100, facilitate the descent of the vessel during the descent of the device.
  • FIG. 178 is an illustration of an embodiment of the current disclosure similar to the embodiment illustrated and discussed in FIG. 175.
  • this embodiment utilizes a "stop" attached to flexible connector portion 1204 in order to limit the maximum separation between the float 1211 and the inertial mass 1223, and in order to indirectly limit the minimum separation between the inertial mass 1223 and flotation module 1201.
  • this embodiment mounts pulley 1214 to a buoyant block 1216 and/or platform which is suspended and/or floats above the inertial mass 1223 and is connected to vessel 1223 by connectors 1217- 1218.
  • Flexible connector portion 1207 passes through block 1216 via a channel 1215 where it connects to the inertial mass via connectors 1219-1220.
  • this embodiment utilizes an inertial mass 1223 that does not possess, incorporation, nor benefit from the utilization of flaps. Instead, this embodiment's inertial mass 1223 relies on an "arrow-shaped" vessel, and a weighted 1224 lower end to facilitate its sinking back to its nominal distance below flotation module 1201 following the conclusion of a "power cycle" involving the rising of flotation module 1201 in response to an approaching wave.
  • FIG. 179 is an illustration of an embodiment of the current disclosure similar to the embodiment illustrated and discussed in FIG. 170.
  • this embodiment utilizes a "pocket" 1306 recessed into a bottom surface of flotation module 1301, similar to pocket 903 in FIG. 175.
  • Pocket 1306 is filled with a gas (e.g. air and/or nitrogen), an oil, or other buoyant liquid.
  • a gas e.g. air and/or nitrogen
  • an oil e.g
  • FIG. 179 omits a connection of the restoring mass to the respective flexible connector by means of, and/or through the use of, a pulley.
  • This embodiment instead connects the restoring weight 1315 directly to flexible connector 1310.
  • the restoring weight 1315 swings 1316 from its nominal, resting position and/or orientation beneath the point at which its limiting tether attaches to flotation module 1301, to a position beneath the point at which its flexible connector 1310 is operatively connected to gear 1307.
  • this embodiment utilizes an inertial mass composed of a tube 1321 sectioned and/or partitioned by a "dividing" wall 1327 normal to its longitudinal axis.
  • flaps in the dividing wall remain closed, e.g. 1324, due to the positive and/or excessive pressure in the upper chamber 1322 of the vessel, and the negative and/or deficient pressure in the lower chamber 1326.
  • the positive and/or excessive pressure in the lower chamber 1326, and the negative and/or deficient pressure in the upper chamber 1322 causes the flaps in the dividing wall to open, e.g.
  • FIG. 180 is an illustration of an embodiment of the current disclosure.
  • the flexible connector operatively connecting flotation module 401 to the respective inertial mass 419, causes to turn gear 405 located beneath, and/or extending below, the bottom of flotation module 401, and thereby transmits rotary energy to a pair of generators housed inside flotation module 401
  • the flexible connector 1422 in the embodiment illustrated in FIG. 180, and operatively connecting flotation module 1401 to the respective inertial mass 1430 directly turns a gear 1405 connected to the shaft of generator 1404, and/or connected to a transmission and/or gear assembly connected to the shaft of generator 1404.
  • the generator(s) of the embodiment illustrated in FIG. 180 are positioned outside flotation module 1401, and are protected within a housing, lid, shroud, canister, and/or pod 1402 attached, e.g. removably, to an upper surface of flotation module 1401.
  • the inertial mass of the embodiment illustrated in FIG. 180 is a constricted tube 1430 with upper and lower mouths.
  • Inside the tube is an approximately neutrally-buoyant spherical plug 1436, connected to inside surfaces of the tube by connectors 1432 and 1438.
  • the spherical plug 1439 will block the constricted portion of the tube, causing the inertia of the water trapped in the upper and lower portions of the tube to resist flotation module's 1401 upward acceleration.
  • FIG. 181 shows an embodiment of the current disclosure.
  • This embodiment further includes an electrical power cable 7-750 adapted to carry electrical power from the generator housed in the converter to a remote electrical grid, such as an onshore grid adjacent to a shoreline of the body of water.
  • the power cable in this embodiment is suspended by floats e.g., 7-755.
  • the power cable is spliced into a subsea power cable near the seafloor.
  • the mechanical energy of the rotating shaft is used to power an apparatus on the converter that performs useful work such as the production of chemical fuels.
  • pulley/capstan 7-125 is a chain wheel, gypsy wheel, and/or wildcat.
  • FIG. 182 shows a top-down view of an embodiment of the current disclosure.
  • Flotation module 650 floats at the surface of a body of water.
  • a collection of guiding pulleys e.g. 657 Arranged in a first circular pattern is a collection of guiding pulleys e.g. 657. Guiding pulleys 657 are arranged around the circumference of aperture 659.
  • Each guiding pulley is associated with a flexible connector e.g. 658.
  • each guiding pulley can rotate about an axis approximately collinear with the line tangent both to the top of the guiding pulley's associated power-take-off pulley e.g. 655 and to the top of the said guiding pulley itself. By being able to so rotate, each guiding pulley can remedy, at least partially, fleet angle misalignments due to flotation module pitch and roll, and direct its associated flexible connector to tis associated power-take-off pulley.
  • power-take-off pulleys e.g. 655 and 660.
  • the power-take-off pulleys can be chainwheels and/or grip pulleys.
  • Each power- take-off pulley is associated with a generator assembly 661, which can include a gearbox and/or a hydraulic circuit for transmission of power and speed-up of rpm.
  • a plurality of flexible connectors e.g. 658 each passes over a guiding pulley and a power-take-off pulley.
  • Each flexible connector is further associated with a peripheral aperture 652 which allows the said flexible connector to pass to the water beneath the flotation module near its location of interface with its associated power-take- off pulley e.g. 655.
  • Apertures 652 each communicate from a top surface to a bottom surface of the flotation module.
  • FIG. 183 shows a cross-sectional view taken at 31 of FIG. 182.
  • a junction ring 662 which further connects with to flexible connector 663 and seafloor anchor 664 which is affixed to the seafloor 665; each flexible connector 658 thus can communicate a tension force from the flotation module 650 to the seafloor.
  • seafloor anchor is shown in this figure, the device design disclosed in this figure is not limited to use with a seafloor anchor, and could be used instead with an inertial mass in place of seafloor anchor 664, in which case each flexible connector would communicate a tension force to the inertial mass.
  • FIG. 183 shows more clearly the central aperture 659 and peripheral apertures 653.
  • Each flexible connector e.g. 654/658 has one end linked to the junction ring 662 and another end "dangling" e.g. 654, with no discrete weight or other object attached.
  • a heavier gauge of chain or cable is used near a dangling end 654.
  • no change in gauge is used.
  • the purpose of the dangling end is simply to provide ample "travel" as the flotation module rises on waves of appreciable height. The lengths shown are not to scale.
  • At least 30 meters of travel is available, meaning that the distance between (i) the power- take-off pulley 655 (and/or the bottom of aperture 652) and (ii) the bottom of dangling end 654 is at least 30 meters. In some embodiments, it is at least 40 meters or at least 50 meters.
  • guiding pulleys 657 can be directional rectification pulleys, meaning that they are mounted on a hinged apparatus or a hanging apparatus that enables them to pivot or rotate to correct for fleet angle misalignments, in particular, pivoting or rotating about an axis approximately collinear with the path taken by flexible connector segment 656, i.e. a line passing tangent to the top of the relevant power-take- off pulley (e.g. 655) and the top of the relevant guiding pulley e.g. 657.
  • flotation module 650 has a sloped indentation 668. [00623] When the flotation module 650 rises on a wave, it translates upward relative to the array of flexible connectors 658, causing said flexible connectors to apply a torque to power-take-off pulleys e.g. 655 and 660, from which electrical power can be generated by generator assembly 661.
  • FIG. 184 shows a top-down view of an embodiment of the present disclosure.
  • a buoy 520 floats adjacent to a surface of a body of water.
  • the buoy 520 contains does not contain any apertures.
  • a roller 522 At one point along the upper perimeter of the buoy is a roller 522 about which is wound the strands of a ribbon cable 526.
  • One side, e.g., 525, of each ribbon cable strand leaves the roller 522 and travels into the body of water where the end of that side of each strand of the ribbon cable is connected to an inertial mass (not visible).
  • each ribbon cable strand leaves the roller 522 and travels to a second roller 523 over which it travels into the body of water and where at the end of each such strand side the strand is connected to a "restoring weight" (not visible).
  • FIG. 185 shows a cross-sectional view of the embodiment of the present disclosure illustrated and discussed in relation to FIG. 184, and taken across section line 25 in FIG. 184.
  • Buoy 520 floats adjacent to a surface 521 of a body of water.
  • a ribbon cable connects a negatively buoyant inertial mass 530 to a restoring weight 534 by means of ribbon junction bars 528 and 532 located at its ends 526 and 531, respectively, which are in turn connected to cables 529 and 533, respectively.
  • the ribbon cable travels across the top of the buoy 520. And, the strands of the ribbon cable are wound around a roller 522 that is rotatably connected to a generator 524 which is able to exert a torque on the roller, the overcoming of which results in the generation of electrical power. The strands of the ribbon cable also travel over and partially around a roller 523 which does not resist the cable's travel.
  • FIG. 186 shows a top-down view of an embodiment of the present disclosure.
  • a buoy 415 floats adjacent to a surface of a body of water.
  • the buoy contains five apertures that facilitate the passage and movement of cables from rollers above its upper surface, to submerged objects below its hull.
  • each pair of rollers e.g. 401 and 400, constituting four two-roller traction winches, are arranged radially about the buoy's upper surface.
  • a ribbon cable e.g. 412, one end of which rises from the water through the central aperture 417, and the other end of which returns to the water through a roller- specific peripheral aperture, e.g. 421.
  • Each strand of each ribbon cable is wound about each of its respective traction winch's rollers.
  • the turning of the peripheral roller in each traction winch turns the rotors of a pair of respective electrical generators, e.g. 418 and 419.
  • FIG. 187 shows a cross-sectional view of the embodiment illustrated and discussed in relation to FIG. 186, and taken across section line 21 in FIG. 186.
  • each ribbon cable is connected to a submerged inertial mass 426 at a connector 428. From there, each strand of each ribbon cable passes through the buoy's central aperture 417 and is wound around the pair of rollers, e.g. 400 and 401, of its respective traction winch. The other end of each strand of each ribbon cable passes through a peripheral aperture, e.g. 416, and is connected to a strand- specific restoring weight, e.g. 429.
  • FIG. 188 shows a perspective view of an embodiment of the current disclosure.
  • this embodiment uses a net 7-143 composed of flexible tendons to substantially enclose and "hold up" inertial mass 7-140.
  • the net 7-143 makes contact with inertial mass 7-140 at a plurality of locations around the inertial mass's perimeter, and/or exterior surface, especially (but not limited to) its bottom portion.
  • the net can be, but is not necessarily, fixedly connected to the outer perimeter of the inertial mass, i.e. in some embodiments the net can make sliding contact with the outer surface of the inertial mass, in some embodiments it does not.
  • An advantage of a net enclosure is that the net 7-143 composed of flexible tendons to substantially enclose and "hold up" inertial mass 7-140.
  • the net 7-143 makes contact with inertial mass 7-140 at a plurality of locations around the inertial mass's perimeter, and/or exterior surface, especially (but not limited to) its bottom portion.
  • inertial mass weighted portion 7-145 is still present in this embodiment, only it has been moved to a position closer to the center of the inertial mass to reduce the possibility of "snagging" on the net.
  • This embodiment includes an electrical power cable 7-750 adapted to carry electrical power from the generator housed in the device to a remote electrical grid, such as an onshore grid adjacent to a shoreline of the body of water.
  • the power cable in this embodiment is suspended by floats e.g. 7-755.
  • the power cable is spliced into a subsea power cable near the seafloor.
  • the mechanical energy of the rotating shaft can be used to power an apparatus on the device that performs useful work such as the production of chemical fuels.
  • pulley/capstan 7-125 is a chain wheel, gypsy wheel, and/or wildcat.
  • Depending connector 7-150 is a chain.
  • the angle of the arc defined by the contact between depending connector 7-150 and pulley/capstan 7-125 can be less than a 2 times pi radians, i.e. depending connector 7-150 can pass around pulley/capstan 7-125 less than full one time.
  • FIG. 189 shows an illustration of an embodiment of the current disclosure similar to the embodiment illustrated and discussed in FIG. 179.
  • FIG. 189 has one or more generators positioned within chamber 1609 which is attached to flotation module 1601 by connectors 1604-1605.
  • chamber 1609 is filled with a gas, e.g. air or nitrogen, and that gas is periodically or continuously replenished through a tube connecting a lower portion of the chamber's interior to a gas-pumping, nitrogen-separating, and/or pressurized gas-dispensing, module positioned within flotation module 1601.
  • the generator is an underwater/marine generator.
  • FIG. 189 utilizes an inertial mass 1626 with an upper orifice 1622 through which the flow 1621 and 1625 of water between the inside and outside of the vessel is controlled by a frusto-conically-shaped plug 1623.
  • the plug 1623 is pulled up into the orifice, thus obstructing any flow of water therethrough.
  • FIG. 190 shows an illustration of an embodiment of the current disclosure similar to the embodiment illustrated and discussed in FIG. 179.
  • flotation module 1701 is connected to inertial mass 1728 by five flexible connector portions 1712-1716.
  • the flexible connector 1712 directly attached 1725 to inertial mass 1728 passes through and/or around, and/or is operatively connected to, four pulleys 1705, 1706, 1723 and 1726, before it engages with and/or turns gear 1707.
  • the effect of this is that every unit increase in the separation of the inertial mass 1728 and flotation module 1701 causes the passage of five units of flexible connector past and/or over the operatively connected gear 1707.
  • This has the advantage of multiplying the rate of the gear's 1707 rotation in response to the rising of flotation module 1701 thereby avoiding and/or reducing the need for additional gears to achieve the same increase in the rate of rotation of the generator's shaft.
  • This has the disadvantage of requiring the use of a longer flexible connector and additional pulleys.
  • inertial mass 1728 is completely sealed.
  • the water, and/or other fluid(s), and/or other solid(s), and/or other gas(es), trapped within the vessel 1728 are unable to escape the interior chamber 1729 of the vessel.
  • This inertial mass utilizes a "pointy" lower end in order to reduce drag when it is drifting down in order to restore its nominal, default separation from flotation module 1701 following the passing of a wave crest.
  • the downward force required to support and/or to accelerate inertial mass 1729 is distributed across five portions 1712-1716 of a flexible connector. This means that any one of those five connector portions typically bears approximately one-fifth of the total force being exerted on the rest of the embodiment by the inertial mass 1729.
  • the downward force required to support and/or to accelerate restoring mass 1722 is distributed across two portions 1717 and 1719 of a flexible connector. This means that when the weight of the restoring mass is not being fully supported by its limiting tether 1718 either of those two connector portions typically bears approximately one-half of the total force being exerted on the rest of the embodiment by the restoring mass 1722.
  • the mass of the inertial mass can be relatively great while its net effective weight can be relatively low (since the surplus in its weight over that of the water which it displaces is relatively small).
  • a restoring mass with an average density significantly greater than that of the water in which the embodiment floats e.g. the density of iron
  • the mass of the restoring mass can be relatively small while its net effective weight can be relatively great (since the surplus in its weight over that of the water which it displaces is relatively great).
  • FIG. 191 shows an illustration of an embodiment of the current disclosure similar to the embodiment illustrated and discussed in FIG. 168.
  • inertial mass 1821 is connected 1818 to a block 1817 through which it is connected, by two flexible connectors 1806 and 1810, to two gears 1802-1803 rotatably connected to flotation module 1801.
  • Each flexible connector 1806 and 1810 establishes, creates, and/or constitutes, an independent connection between block 1817 and flotation module 1801.
  • a restoring weight 1812 connected to an end of each flexible connector 1807 and 1809 provides a shared and/or common restoring force to those flexible connectors, and indirectly to inertial mass 1821.
  • Restoring weight 1812 moves up and down in a manner constrained by the flexible connectors 1806 and 1810 that pass through channels 1813 and 1815 in weight 1812.
  • Inertial mass 1821 is open to the surrounding water 1800 at its top. Its shape approximates that of an "elliptic paraboloid" which might be expected to produce an advantageous distribution of forces across the lateral and lower surfaces.
  • FIG. 192 shows a top-down cross-sectional perspective of the inertial mass 1821 taken along line AA in FIG. 191.
  • Struts e.g. 1901, spanning the upper mouth of tube 1900 support the connection of the vessel 1821 to the block 1817 and distribute the load imparted to the vessel from the block 1817.
  • FIG. 193 shows an illustration of an embodiment of the current disclosure similar to the embodiment illustrated and discussed in FIG. 179.

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  • Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Other Liquid Machine Or Engine Such As Wave Power Use (AREA)

Abstract

L'invention concerne un dispositif houlomoteur qui génère de l'énergie à partir d'une séparation induite par les vagues d'un module de flottaison à flottabilité positive et d'une masse immergée à flottabilité négative, au moyen d'un couple transmis à une poulie rotative pour entraîner un système de prise de force.
PCT/US2017/051000 2016-09-11 2017-09-11 Dispositif houlomoteur à inertie WO2018125318A2 (fr)

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NZ752276A NZ752276A (en) 2016-09-11 2017-09-11 Inertial wave energy converter
AU2017385006A AU2017385006B2 (en) 2016-09-11 2017-09-11 Inertial wave energy converter
ZA2019/02186A ZA201902186B (en) 2016-09-11 2019-04-08 Inertial wave energy converter

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US201662393056P 2016-09-11 2016-09-11
US62/393,056 2016-09-11
US201662426328P 2016-11-25 2016-11-25
US62/426,328 2016-11-25
US201662430354P 2016-12-06 2016-12-06
US62/430,354 2016-12-06
US201662435895P 2016-12-19 2016-12-19
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NO20210008A1 (no) * 2021-01-06 2022-07-07 Hoelleland Jarle Vinsjdrevet bølgeenergikonverter med hydraulisk effektbegrenser
WO2023105250A1 (fr) * 2021-12-09 2023-06-15 JSC Zago Technology Centrale houlomotrice dotée d'un moufle d'accélération

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WO2023105250A1 (fr) * 2021-12-09 2023-06-15 JSC Zago Technology Centrale houlomotrice dotée d'un moufle d'accélération

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WO2018125318A3 (fr) 2019-04-18
WO2018125318A9 (fr) 2018-08-23
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NZ752276A (en) 2023-06-30
AU2017385006B2 (en) 2023-03-30

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