Not Applicable
1. Field of the Invention
This invention relates to electrical power systems. More particularly, it relates to a system for supplying power to an electrical grid system from a floating vessel having storage means for electrical energy.
2. Description of the Related Art Including Information Disclosed Under 37 CFR 1.97 and 1.98
Some renewable electric power generation facilities produce electric power intermittently or in small quantities because renewable electricity can only be generated when the source energy is available in the environment. In contrast, electricity must be dispatched to the market when needed and in the amounts required. When renewable electric power generation capacity is relatively small, as it is now, conventional dispatchable sources of electricity, such as distributed gas fired power plants, are taken online/offline to accommodate the availability of renewable energy sources, but this is not an economic long-term solution due to start-up and shut-down cost of the stand-by generating units. Increasing amounts of energy storage will be required as more renewable electrics are connected to the grid. Energy storage capacity bridges the disconnect between the supply and demand for renewable electricity and adds value to renewable electric installations much as oil storage adds value to remote oil reserves.
Although the growth of renewable electrics highlights the need for energy storage on the grid, Energy Storage Systems (ESS) are already being added to the grid for other reasons. For example:
1. Load-shifting. ESS can be used to accumulate lower-cost, off-peak electric energy for later sale at higher rates. This presents financial opportunity and also has the real benefit of allowing deferral of investment in transmission, distribution, and generation facilities.
2. Ancillary grid services. ESS can provide critical ancillary services such as frequency regulation and voltage support that improve grid stability and reliability.
One illustrative embodiment of the invention comprises an Electric Floating Storage and Offloading system that: (1) may be moored at a location convenient for connection to the power grid; (2) supports an array of grid-scale batteries; and, (3) provides means for delivering stored electrical energy to the power grid or to an end user. In another embodiment, an accompanying crane barge lifts energy storage modules (e.g., grid-scale batteries) from a transport vessel (e.g., a barge) onto a shore foundation so that the facility transport barge can be released.
Another embodiment of the invention provides an energy transport system for supplying an electrical grid with power previously produced at another location (e.g., a renewable energy source). An exemplary embodiment comprises: an offshore source of electrical energy (e.g. wind, wave, tidal, ocean thermal, etc.); an energy storage device on a vessel [e.g., grid-scale batteries]; and, a shore-side (or river-side) electrical connection to a grid (to which the energy storage device may be transported by and connected). In another embodiment, stranded offshore gas reserves are used as fuel to generate electricity (at an offshore location) which may then stored in an ESS on a vessel for transport to an onshore grid connection.
Yet another embodiment of the invention permits electrical energy to be deployed in or near shipping lanes to replenish hybrid electric vessels (analogous to the “oilers” used to refuel naval vessels that use petroleum-based fuels). In this embodiment, one or more vessels carrying an energy storage device (or array of such devices) are stationed along a predetermined route of a hybrid electric vessel. The deployment positions may be at or near a renewable energy source thereby permitting the energy storage device to be charged. During the replenishment operation, the vessel having the ESS may be brought alongside the hybrid electric vessel and an electrical connection may be made which enables a transfer of electrical energy from the storage vessel to the hybrid electric vessel. As is now done with oilers, this may be accomplished while both vessels are underway.
Several types of battery technologies are evolving in the US/EU in response to large R&D programs in the automotive, utility, and defense industries. Grid-scale batteries have been put into service at locations in the US and abroad. These facilities have been constructed on location using truckable modules and components. A publication indicated that budget, schedule, and/or relocation was an issue on at least one of these projects.
Many population centers, and therefore centers of electric power demand, are located in coastal areas or along navigable rivers. The type of vessel that supports the ESS may depend on the specifics of the application and the given marine environment. For example, if electricity were to be stored near a coastal load center like Monaco or New York City, the batteries may be integrated into a ship-shape, semisubmersible, or barge that offered reasonable motions in that marine environment. If energy storage were to be provided to a city on a river, e.g., St. Louis, Mo., the battery array may be integrated into a barge that may be transported on an oceangoing vessel, offloaded, and towed to final location on the river (
An e-FSO may also be located along shipping lanes and store energy for periodic discharge into hybrid electric ships (
Various types of energy storage devices may evolve to be supported on a marine vessel. A mechanical battery, which is a special type of e-FSO, may be possible when: (1) the marine climate is mild and (2) deepwater is relatively near the coast and grid-connection points. As shown in
An e-FSO according to the present invention offers the following advantages:
Large ESS's may be located near major cities and load centers without requiring expensive coastal real estate.
Advanced technology batteries may be located at safe distances from populated areas. This may be an advantage as certain grid-scale batteries operate at high temperatures and/or contain hazardous materials.
Additional units may be installed over time as energy storage requirements increase.
The battery array on a given vessel may be changed out as battery technology improves over time.
Energy storage units may be relocated as generation and load centers change over time. In some cases, an e-FSO according to the present invention may allow deferral of power generation facilities by enabling storage of off-peak energy for later discharge during daily peak demand.
Large battery arrays may be cost-effectively integrated into the vessel at a manufacturer, shipyard, or fabrication yard and economically transported to the installation site. On-site construction work may be minimized.
Energy storage units may be justified initially by enabling the purchase of energy at low off-peak rates for resale that same day at higher peak rates. As renewable electrics are added in a region, expandable energy storage infrastructure would already be in place to aggregate renewable energy and create more valuable dispatchable energy.
As will be appreciated by those skilled in the art, much of the technology used in FPSO vessels used in petroleum production may be adaptable to the practice of the present invention.
Referring now to
In the illustrated embodiment, battery 110 on e-FSO 105 is charged by renewable energy source 312 while battery 110′ on e-FSO 105′ is charged by renewable energy source 310 which may be the same or a different type of energy source as 312.
Also shown in
Although the invention has been described in detail with reference to certain preferred embodiments, variations and modifications exist within the scope and spirit of the invention as described and defined in the following claims.
This application claims the benefit of U.S. Provisional Application No. 61/372,761 filed on Aug. 11, 2010.
Number | Date | Country | |
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61372761 | Aug 2010 | US |