Significantly, the system can operate in a non-intrusive manner in the environment in which it is located. FIG. 14 shows another embodiment of a manner of deploying a system 10. In this arrangement, one or more systems 10 can be deployed off of a barge 16. The leading end portion 90 of each system 10 can be supported by any suitable structure, such as arm 140. The system 10 can extend cantilevered from the arm 140 such that the aft end portion 92 of the system 10 is not supported. FIG. 13 is a side elevation view a fluid-based power generation system, showing the system being deployed off of a barge and an underside of the system being supported by a buoyant member. FIG. 14 is a side elevation view a fluid-based power generation system, showing the system being deployed off of a barge and being angled relative to the flow.
Dolor Neuropático Periférico
For instance, a leading end portion 90 of the system 10, such as the forward rotatable member 22, can be operatively attached to the barge 16 by one or more lowering members 26. Additional support to the leading end portion 90 of the system 10 can be provided. For instance, the canopy body 38 can be made of high strength fibrous materials such as carbon fibers. Parches para el dolor de espalda . The canopy body 38 of the catchment devices 34 can be made of a strong and durable cloth-like material. In one embodiment, the catchment devices can be parachutes. FIG. 12 is a top plan view of a fluid-based power generation system, showing a plurality of the catchment devices of FIG. 6, the attachment arms 60 can be downstream of the catchment device 34 relative to the direction of fluid flow 14 when the catchment devices are in the open position.
The catchment device can react with a fluid flow to open in the direction of the fluid flow to thereby transmit energy from the fluid flow to drive the loop member. With the system 10 placed in the fluid flow 14, the flowing fluid can react with the fluid catchment devices 34 located on a section of the continuous loop member 30 that is moving in the direction of the flow 14 so that the catchment devices 34 are inflated, deployed or otherwise opened. The catchment devices 34 can have any suitable form. FIG. 5 shows one example of an attachment arm 60. Each attachment arm 60 can include a first member 62 and a second member 64 that can connect between the continuous loop member 30 and the catchment device 34. Each of the first and second members 62, 64 can have a proximal end 66 and a distal end 68. The proximal end 66 of the first member 62 can be attached to the continuous loop member 30 and can extend substantially perpendicularly outward therefrom.
The first and second systems can each include a continuous loop member, a forward rotatable member that supports a portion of the loop member, and an aft rotatable member that supports another portion of the loop member. The system can further include a support rod. The connectors can be further attached to the attachment arm and/or the support rod.
The system further includes a plurality of fluid catchment devices. As the collapsed catchment device 34 passes around the forward rotatable member 22, the catchment device 34 will open as the fluid flow 14 reacts with it. Because the catchment devices 34 are connected to the attachment arms 60, the catchment devices 34 are spaced from the continuous loop member 30 and do not contact the continuous loop member 30 nor do they contact the rotatable members 22, 24 as the catchment device 34 round the rotatable members. Various prior systems have been directed to generating energy from natural sources; however, they all have inherent design features that render them ineffective and/or inefficient. The system can be rotatable about the shaft and/or vertically movable along the shaft The forward rotatable member can be operatively connected to an electric generator. Dolor de espalda despues de correr . The proximal end 66 of the second member 64 can be attached to the continuous loop member 30 and can extend outwardly various angles as required as it rotates around the rotatable members 22, 24. In one embodiment, the second member 64 can extend at about 45 degrees relative to the continuous loop member 30. The distal end 68 of the first member 62 and the distal end 68 of the second member 64 can be attached together but remain articulating.
The support members 94 can be angled relative to the lowering members 26. In one embodiment, the support members 94 can be angled at less than about 90 degrees relative to the lowering members 26 and, more particularly, at about 45 degrees or less relative to the lowering members 26. The support members 94 can be any suitable structure and can be made of any appropriately strong material. 5, the cords 40 can be attached directly or indirectly to the attachment arm 60, such as at or near the distal end 68 thereof, or any other suitable structure. The lowering members 26 can operatively attach the shaft 100 to one end of the system 10, such as the leading end 90 of the system 10. The attachment of the lowering members 26 to the shaft 100 can be direct or indirect and can be achieved in any suitable manner. When the catchment devices 34 are in the open position, the attachment arms 60 can be upstream of the catchment device 34 relative to the direction of fluid flow 14. In a leading configuration, as depicted in FIG.
For instance, the fluid catchment devices 34 can be substantially equally spaced along the continuous loop member 30. Any suitable quantity of catchment devices 34 can be used. For instance, the lowering members 26 can be mechanically attached to the barge 16 or any other platform via cross bracing or other suitable means. At least one of the rotatable members can be supported by operative connection to a barge. FIG. 3 is a side elevation view of a fluid-based power generation system, showing one end portion of the system as being associated with a barge and another end portion of the system being supported by a buoyant member.
5, or a leading configuration, as is shown in FIG. 10, and an open position, as is shown in FIG. Each catchment device includes an open position and a closed position. In such case, the rotation of the pulley may stop such that the device ceases to function as designed, or the sail may be torn, thereby rendering the sail inoperative. Natacion dolor lumbar . The system will not appreciably inhibit the flow of vehicular or water traffic near the device. The ability of the system to produce large amounts of power from the movement of water without disrupting or altering the flow and its associated environments makes it preferable to other methods. The system 10 can be supported in the flowing body of water 12 by a support structure. The trailing end 92 of the system 10 can be at least partially supported by a buoyant member, such as a variable buoyancy buoy 96. A generator (not shown) can be housed within the buoyant member.
A plurality of sails is attached to the flexible member. U.S. Pat. No. 3,992,125 to Schilling is directed to an underwater power apparatus with furlable sails as working members. As a result, all of the flexible members will be at the same level and will most likely cause an entanglement of the flexible member and sails. The second member can provide support to the first member against bending. The first length can be different from the second length. In another embodiment, the first and second systems are arranged in a substantially v-shaped configuration.
The potential for generating power is enormous.
However, the systems 10 can be arranged in any suitable manner. DETAILED DESCRIPTION Embodiments are directed to systems for harnessing the energy in fluid flows. The foregoing description is provided in the context of one possible application for embodiments of a fluid-based power generation system. Embodiments will be explained in connection with various possible arrangements of a water-based power generation system, but the detailed description is intended only as exemplary. The potential for generating power is enormous. The amount of energy that could be generated from the Gulf Stream, ocean inlets, tidal waters, rivers and streams is an enormous power source that is virtually untapped when compared to its potential. Dolor de ovario y pierna . As the flexible member reaches the end at the pulley, where it now needs to turn downward to begin its path against the current, the buoyancy correcting member will not allow the rope to sink to a lower depth. A drive shaft 28 can be contained within the lowering member 26. This drive shaft 28 can interface with a drive shaft 28 housed within the vertical shaft 100, such as by a worm gear drive.
In one embodiment, there can be at least three cables 104 and anchors 106. The generator 18 can be mounted on the shaft 100. The generator 18 can be housed within an enclosure (not shown), which can be hermetically sealed. In this arrangement, the generators 18 can be provided within the buoyant members, such as in a hermetically sealed compartment. Alternatively, the generators 18 can be located on land, such as on a land-based fixed provided on a shoreline or banks of an inlet.
- Alteraciones radiológicas de intestino delgado
- Además, procura masajearlos un par de minutos cada uno, Luego, enjuaga
- El dolor agudo de rodilla comienza de repente, por ejemplo después de una lesión
- Portugal reabre este sábado las fronteras con España, cerradas desde enero
The generators 18 can also be located on an offshore platform, such as an oil drilling platform. The rotatable members 22, 24 can be operatively connected to the generators 18 such that the rotation of the rotatable members 22, 24 is transferred thereto. The forward rotatable member can have an associated axis of rotation, and the aft rotatable member can have an associated axis of rotation. The forward rotatable member 22 can have an associated axis of rotation 23, and the aft rotatable member 24 can have an associated axis of rotation 25. In one embodiment, the system 10 can be arranged such that the axes of rotation 23, 25 can be oriented substantially horizontally, as is shown in FIGS. There can be a forward rotatable member 22 and an aft rotatable member 24 relative to the direction of flow. The shaft can be oriented in a substantially vertical direction.