Here, when the fluid flow 520 reaches the Magnus cylinder 500 which is rotating in direction 501, the flow is diverted around the cylinder causing higher pressure in flow stream 505, and lower pressure in flow stream 506. The gradient of flow stream 505 and flow stream 506 results in lift 510. This scheme is termed an on-axis Magnus system. Magnus forces used the rotating cylinders in a fluid environment where the axis of rotation of the cylinder was horizontal, and the fluid movement was also horizontal but generally perpendicular to the axis of rotation of the cylinder, the resulting force direction was often in a vertical or “up” direction, and thus the term Magnus “lift” is often used to refer to this Magnus force, even when the actual direction of the force is not always in an upward direction. Magnus cylinders again as shown in Figure 4, versus the rotation of Magnus cylinder in RPMS in a water flow of at 2 feet per second.
Magnus type wind power generator that includes a horizontal rotary shaft for transmitting torque to a windmill-like power generating mechanism. The pump 5000 input for the fluid is 5010, and the output from the pump 5000 is 5020. As before, fluid pumped can be a gas like air, or a liquid like water.
Dolor Espalda Lado Derecho
As before, this at least one Magnus cylinder may be affixed by a mechanism attached to its first axis of rotation to the outer portion of a central shaft that rotates on an axis substantially parallel to the direction of a fluid moving at a fluid velocity with a direction and speed.
This lesser fluid drag in turn increases system efficiency. Interestingly and unexpectedly however, this fluid flow acceleration in energy harvester chamber 12 is further amplified by the Magnus cylinders themselves, additionally increases the Magnus force lift. The Magnus cylinders may be longitudinally separated in pairs so that flow from the first or leading cylinder is accelerated and further accelerated by the second or next cylinder which is in the rear of the first cylinder and positioned at least 30 degrees out of phase but not more than 179 degrees out of phase of the first cylinder. This also allows the fan device to be larger than the flow channel so that the fan can develop the appropriate torque to rotatably drive the Magnus Cylinders. By locating the finned device near the fluid intake the finned device cause turbulence and the turbulence is beneficial to the lift created by the Magnus cylinders.
The present invention uses fin or finned device (e.g. Dolor de cervical y espalda . A particular advantage of this approach is that for either gas (e.g. The present invention provides an improved Magnus type fluid (e.g. This fluid flow intensification scheme can be used in any of the embodiments envisioned by the present invention. The channel side walls can also be curved (See FIG 5), either in the side or bottom walls in this configuration, and can also have opposite elevations in the plane parallel to the fluid flow path. For example, the inflow fluid channel can be connected to one or more of a sewer, a water treatment facility, a water drain, a holding pond, aqueducts, a roof drain, outflow from a dam, an air conditioning line, and a holding tank. As in other embodiments, the energy harvester may be connected to a suitable electric generator, which may be mounted on the vessel in a water tight chamber or which may be remotely located.
Dolor Neuropático Crónico
In such an embodiment, the energy harvester may be located just below the surface of the water, where the current velocity is greatest, and the harvester may be retained in that location by virtue of the rise and fall of the vessel with the water. The rotating inner shaft can then communicate rotational energy to the various Magnus cylinders (in the first direction), often through a gear arrangement. FIG. 3 is a schematic top view representation of a radial device with staggered rotating Magnus cylinders in an axial position within a channel defined by walls. This central shaft may have an axis of rotation, as well as a substantially cylindrical interior that also has a second inner shaft positioned inside the central shaft, and this inner shaft will be capable of rotating independently about the central shaft’ s axis of rotation.
Tipos De Dolor Torácico
This application claims the priority benefit of U.S. This application is a continuation in part of, and claims the priority benefit of, US patent application 12/691,951, flied January 22 2010; US patent application 12/691,951 in turn claims the priority benefit of U.S. This Magnus force or lift can be used, for example, to rotate a horizontal rotary shaft, which in turn can be harnessed to do useful work, such as electrical power generation. The fin device 88 can be located at either the proximal or distal end of the Magnus cylinder drive shaft 1045 when viewed from the fluid flow 90 (not shown) perspective.
Dolores Musculares Y Fiebre
The fin device 88 can be located at either the proximal or distal end of the Magnus cylinder drive shaft 1045 when viewed from the fluid flow 90 perspective. Then, with the aid of force transuding mechanisms (everything from gears and belts to even electrical generators and motors), this torque generated by the interaction between the moving fluid and the at least one fin will be translated into rotary motion of this at least one Magnus cylinder about its first axis. The Magnus cylinders may be rotated by a drive mechanism as shown in FIG 6. As a result of fluid flow 90, the fin device 88 drives shaft 1045, which in turn drives the bevel gears 1050, 1055, 1060 and 1065 as previously discussed. As shown in FIG 3, the fin device 88 may be located on Magnus cylinder drive shaft 1045, and is rotated by fluid flow 90. The imparted rotation from the fin device 88 (due to fluid flow 90) in turn drives shaft 1045. Gases y dolor lumbar . Shaft 1045 in turn drives the bevel gears 1050, 1055, 1060 and 1065, which are shown in more detail in FIG.
Dolor Espalda Baja
FIG. 21 shows a typical fin means in the form of a turbine blade. Thus replacing the Magnus cylinder drive motor with a fan device has several advantages. Magnus cylinders at higher rotational speeds, including speeds in excess of the wind or fluid velocity, thus overcoming the prior art problems associated with Savonius rotors, while at the same time avoiding the higher expense, lower reliability, and electrical power consumption problems associated with the use of electrical motor Magnus cylinder rotation methods. FIG. 14 is a schematic representation of a double concentric shaft used to drive the Magnus cylinders and transmit the power to the generator which then creates Hydrogen and oxygen.
The invention’ s novel use of a fan Magnus cylinder rotation device, which can be configured to extract only enough energy from the incoming fluid (air or water) to rotate the Magnus cylinders, offers the additional advantages that the fan device also causes additional turbulence, with reduces the drag of the Magnus cylinders, so that they can rotate faster around the central shaft. The supplemental Magnus cylinder rotation motor 1005 can be operable under electric, pneumatic, or hydraulic power, and can also be reversible to allow the rotation of the central shaft 40 to be the same direction if the flow 90 is reversed. The device will make use of suitable gearing or other force transuding mechanisms to translate the motion of this central shaft into the rotary motion of the various (at least one) Magnus cylinder(s) about their respective first axes. This outer shaft will then often will be in communication with an electricity generator, and the captured energy will then be harnessed to perform useful work.
- Dejar de escribir cuando alguien se acerca
- Dolor de muelas
- Apparatus as defined in claim 5, wherein said member is a generally upright sail structure
- Bajada del recuento de glóbulos blancos
- Mejorar el autoconocimiento
- Ayuda a prevenir el envejecimiento prematuro
For higher efficiency, often this at least one Magnus cylinder will be a plurality of Magnus cylinders, and at least some of this plurality of Magnus cylinders may be mounted on the same location on the outer cylinder (relative to the axis of rotation of this outer cylinder, and positioned equidistant from each other along the circumference of this outer cylinder). The more turbulent fluid flow 90 will in turn interacts with the Magnus cylinders in a way that both reduces the drag of the Magnus cylinders and allows them to rotate faster, further increasing the energy produced by the energy harvester. Other prior art rotary Magnus designs used a different approach. Prior art on such Magnus type power generation methods and devices includes U.S. Digitopuntura dolor de espalda . To increase the torque caused by the Magnus force lift, multiple Magnus cylinders may be used. 1, 2 and 3. Here the energy harvester is mounted to a structure where the energy harvester is in communication with a fluid flow 90. As shown in Figure 7 and 8 the power produced is higher when fined device is utilized to drive the Magnus cylinders.
Dolor Espalda Cáncer Pulmón
Note that each successive Magnus cylinder may, but need not, have the same cylinder diameter. Such curved or shaped wall can act as a concentrator for the fluid flow by channeling a greater volume of fluid to the energy harvester, again thereby increasing the speed of the fluid, which in turn will increase the lift generated by the cylinder. That is, the diameters of the cylinder 1200 andl210 may be the same, or they may vary relative to each other. The invention also teaches an air flow device that may be used to increase the Magnus lifting force, which may be installed on the outer peripheral surfaces of the rotary cylinders. The energy harvester may comprise inflow fluid channel walls 4, 5, 6 and 7, as well as energy harvester channel side walls 8, 9, 10, and 11 that receive a flow 90 from the fluid inflow channel walls 4, 5, 6 and 7. A main shaft 40 may be located within a channel 95, defined by the inflow fluid channel walls 4, 5, 6, and 7 and the channel side walls 8, 9, 10, and 11 in which the fluid flow 90 is received.