Turbine assembly and energy transfer method

A turbine assembly comprises 2 or more symmetrical vanes or blades attached to a centralized shaft. The assembly may be placed into a fluid current for transferring energy therefrom. Each blade has a scoop with a relatively broader span at the top end and a relatively narrow span at the bottom, which scoop-like vane or blade resembles an inverted tear drop. Eighty-six percent of the potential energy vector is captured within the blade assembly. One end may be connected to a power generation device that will create electrical power when rotated. Certain energy transferring methodology is believed further supported by the vane or blade designed incorporated into the overall turbine assembly.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention generally relates to a turbine for transferring energy from a fluid current. More particularly, the present invention relates to a turbine assembly having uniquely configured inverted tear drop shaped vanes or blades for reacting to a fluid current driven thereagainst and transferring said reaction to a centralized rotatable shaft.

2. Description of Prior Art

U.S. Pat. No. 4,293,274 ('274 Patent), which issued to Gilman, discloses a Vertical Axis Wind Turbine for Generating Usable Energy. The '274 Patent describes a wind turbine for converting wind forces into usable energy having a main shaft rotatably mounted in the axis of rotation for the wind turbine, and a pair of coacting complementary longitudinally extending vane members are connected to each other by a plurality of support and transmission assemblies in the form of articulated members and to the main or driven shaft for driving engagement thereof.

The coacting vane members of the device shown in the '274 Patent may either have straight side edges or preferably have spiralled or helically shaped side edges which in the closed position are aligned and in abutment with each other to define and form a right circular cylinder in side elevation. The vanes are movable between a normally open starting position and a closed position to vary the total vane surface available for contact by the wind forces acting at any given time when the wind turbine is in operation.

Articulated members of the support and transmission assemblies are pivoted to permit translational or side wise movement to and fro of the complementary vanes transverse relative to each other and the vertical axis through the main shaft, and pivotal cross members on each of the articulated support and transmission assemblies are vertically linked together to simultaneously alter the articulated members during such movement.

The respective complementary and cooperating vanes have their weight so distributed that centrifugal forces will act to move the complementary vanes towards the closed or right circular cylindrical form automatically as high rotational speeds result from excessive wind. Additionally the wind turbine as above described with resilient means to move the coacting cooperating vanes to the normally open starting position.

U.S. Pat. No. 5,405,246 ('246 Patent), which issued to Goldberg, discloses a Vertical Axis Wind Turbine with a Twisted Blade Configuration. The '246 Patent describes a vertical-axis wind turbine having two or more elongated blades connected to a rotor tower. The tower defines an axis of rotation and is linked, preferably via a gearbox or other torque-converting arrangement, to the shaft of a generator.

Each blade is “twisted” so that its lower attachment point is displaced angularly relative to its upper attachment point. In a preferred embodiment, the radial distance of each blade from the axis of rotation varies between upper and lower attachment points such that the blade lies approximately along a “troposkein”, which is the shape assumed by a string clamped at each end and spun about an axis passing through the ends of the string.

The ratio between blade chord length and blade thickness is preferably constant over the length of each blade, with the middle of each blade approximately 80% as thick as its ends. The cross-section of the blades may be teardrop-shaped, shaped as an airfoil, rectangular, or curved in some other way.

U.S. Pat. No. 6,465,899 ('899 Patent), which issued to Roberts, discloses an Omni-Directional Vertical-Axis Wind Turbine. The '899 Patent describes an omni-directional, vertical-axis wind turbine comprising a rotor/stator combination which maximizes energy production by increasing wind velocity and pressure plus eliminating back pressure. The stator section includes a plurality of vertical blades secured between upper and lower conical sails.

The blades have a radius fundamentally equal to that of the rotor and a chord length approximately 1.25 times its radius. The rotor has a diameter approximately equal to one-half that of the stator and has a plurality of concave blades secured to and spaced from a vertical spindle, said blades being arranged in stages within the vertical rise of the rotor. Each rotor blade has a chord line equal to twice its radii and a chord length approximating one-third the diameter of the stator.

U.S. Pat. No. 7,314,346 ('346 Patent), which issued to Vanderhye et al, discloses a Three-Bladed Savonius Rotor. The '346 Patent describes a Savonius style three bladed vertical axis wind turbine rotor has operational characteristics superior to those of conventional three bladed rotors. The blades have high curvature and a high skew factor, for example a curvature of greater than 7:1 (e.g. 2:1-5:1), and a skew factor of greater than 0.6 (e.g. 0.78-0.9).

The rotor also includes at least one vertical shaft, the blades operatively connected to the shaft. The rotor typically has an aspect ratio of at least 2:1. The rotor typically has a maximum power coefficient (Cp) of at least twice that of an otherwise identical rotor with a skew factor of 0.5 or less. The rotor can drive a generator with a drive which automatically increases the effective gear ratio as the rotational speed of the rotor increases; or the rotor can be connected to a propeller of a multihull wind powered boat.

U.S. Pat. No. 7,362,004 ('004 Patent), which issued to Becker, discloses a Wind Turbine Device. The '004 Patent describes a hybrid blade wind turbine device formed of at least a pair of straight outer airfoil blades, and a pair of inner helical wing blades, as supported for rotation within a safety protective cage structure, which wind turbine can be mounted in the vertical, horizontal, or other aligned operational positions.

The inner helical half wing blades, being preferably somewhat shorter than the length of the outer airfoil blades, act to “regularize” the swirling wind regime flowing through the hybrid wind turbine, so as to maximize the efficiency of the outer airfoil blades. The helical half wing blades can be formed of individual segmented vane segments to provide improved operational capabilities for the overall hybrid wind turbine. To best harness annualized available wind conditions, the hybrid wind turbine can be customized, through modification of the number of vane segments, the selection of the specific shape of the outer airfoil blades, and the specific operational positioning of the outer airfoil blades. Alternatively, the helical half wing blades can be formed as generally smooth-walled blades.

United States Patent Application Publication Number US 2007/0104582, which was authored by Rahai et al., describes a high efficiency vertical axis wind turbine having an optimized blade shape for increased torque output. The shape of the optimized profile includes a camber portion at a leading edge region of the blade with a maximum height to chord ratio (Y/C) at when the non-dimensional chord length (X/C) is approximately one third. An intermediate region follows the leading edge region and is characterized by a shallow convex region, followed by a flow reattachment surface at the trailing edge region characterized by a second concave region and a local maximum of the height to chord ratio at approximately four fifths of the non-dimensional chord length.

United States Patent Application Publication Number 2008/0095631, which was authored by Bertony, describes a vertical axis wind turbine comprising three vertically extending sails where each sail comprises a strip of substantially constant width. The opposite ends of each sail are longitudinally twisted to have a pitch angle of approximately 90 degrees. The turbine further comprises a vertically extending central core and a vertically extending opening between each sail and the core.

Also disclosed is an improvement in a vertical axis wind turbine having at least one main blade each of which has a longitudinal extent and a longitudinally extending radially outermost edge. The improvement comprises a longitudinally extending auxiliary blade spaced from the main blade to define a venturi inducing gap between the main blade and the auxiliary blade whereby the turbine has a zone of influence which extends radially beyond the maximum radial extent of the blades.

It will be seen from a review of the prior art that the art fails to disclose a turbine assembly having scoop-like tear drop shaped rotor blades or vanes for capturing fluid current directed thereagainst within a range of 155 rotational degrees. The prior art thus perceives a need for such a turbine or rotor assembly as described in more detail hereinafter.

SUMMARY OF THE INVENTION

A turbine is essentially a rotary engine that extracts energy from a fluid current, as may be exemplified by water or wind currents. The simplest turbines have one moving part, a rotor assembly, which essentially comprises a shaft with blades or vanes attached thereto. Moving fluid or a fluid current (such as water, steam, or air (wind)) acts on the blades, or the blades react to the flow or fluid current, so that they rotate and impart energy to the rotor assembly.

The current technology of relatively small scale wind turbines is regionally challenged due to inadequate average wind speeds. Less than 50% of the United States can use existing wind turbines in a cost efficient manner due to the need for average wind speeds of 25 miles per hour or better. The blade according to the present invention provides a scoop-like, inverted tear drop design, which design is optimized to harvest available wind stream and the wind amplifications that result at the apex of the structure.

The efficiency that results in a lower start up and constant wind speed of 12 miles per hour effectively increases the regional area that wind energy can be used in the United States by 25%. The invention is designed to deliver, for example, a rated power of 2500 watts with an approximate wind speed of 12 miles per hour (MPH). Current or state of the art turbines are relatively inefficient for capturing and transferring energy from turbulent wind sources as compared to the present invention since the inverted tear drop vane or blade design is capable of capturing fluid currents directed thereagainst within a relatively large range of current direction.

It is further noted that current or state of the art wind turbines are expensive with many and complex assortment of moving components, as compounded by the requirement for elevated mounting on costly towers. The relatively small blade design according to the present invention is optimized to be mounted on a structure's APEX roof making a tower unnecessary. Accordingly, the relatively small design enables potential users to makes use of the invention in urban areas including residential homes and small businesses.

This invention generally relates to a turbine assembly having multiple symmetrical blades to harness fluid currents (primarily wind currents) to turn a generator to create electric power. Wind power is a low cost alternative to fossil fuels and has become a growing market since the US government is providing tax credits for installation. The problems that have been noted with state of the art wind turbines is that they have expensive installation costs, require large acreage; and require a high constant wind requirement that excludes many parts of the United States where wind turbines can be used.

The blade design and assembly incorporating the same according to the present invention increases efficiency and use of wind from more directions and funnels the wind from previous blade into force of adjacent blade to further rotatably drive the rotor assembly. The turbine assembly can be mounted on top of a structure or a tower for easy low cost installation, but has also demonstrated effective rotation in water current for application in hydro electric power generation.

DESCRIPTION OF THE PREFERRED EMBODIMENT(S)

Referring now to the drawings with more specificity, the preferred embodiment of the present invention is a vertical axis type turbine assembly10having a series of vanes11or blades substantially equally spaced about the circumference or body of a rotatable spindle or shaft12for transferring energy from a fluid current as generally depicted at arrows100. The rotor or turbine assembly10according to the present invention preferably comprises a central shaft12and a series of vanes11(preferably three), which three vanes11or blades are generally spaced 120 degrees from one another as generally depicted inFIGS. 8 and 8(a).

As generally depicted in the various figures, the shaft12is rotatable about an axis of rotation as at101, and may be outfitted with a generator or certain similar means for generating electricity (not specifically illustrated). The vanes11are each attached to the shaft12about its circumference and may be described as having an inverted, scoop-like, tear drop shape. Each vane or blade11thus comprises a generally arched, arced or C-shaped cross section102through a transversely oriented first plane as generally depicted inFIG. 8(a).

Further, each vane or blade11comprises a generally (and inverted) hooked or J-shaped cross section103through a sagittally oriented second plane orthogonal to the first plane as generally depicted inFIG. 2(a). Notably the C-shaped cross section102is preferably orthogonal to the axis of rotation101and the J-shaped cross section103is parallel to the axis of rotation101.

Given the generalized shape of the cross sections102and103, the vanes or blades11each have a generally convex outer surface20and a generally concave inner surface21. The concave surfaces21essentially function to capture a fluid current (as at100) directed thereagainst or thereinto, and the convex surfaces20essentially function to deflect fluid current100thereabout.

Each vane or blade11further comprises a radially inner edge as at50, and a radially outer edge as at24. The convex outer surfaces each preferably oppose and abut the central shaft12at superior vane portions (as at60) and the inner radial edges50oppose and abut or extend from the central shaft12at inferior vane portions (as at61).

The convex outer surfaces20each preferably helically wrap around a portion of the central shaft12(as generally and comparatively depicted inFIGS. 2-4for deflecting the fluid current into the concave inner surfaces21such that the concave inner surfaces capture deflected fluid current for increasing the first current pressure relative to the second current pressure.

The concave surfaces21and convex surfaces20are respectively associated with a first force or pressure and a second force or pressure, which first pressure is greater in magnitude than the second pressure for imparting a torque through or coaxial with the axis of rotation101and rotating the shaft12thereabout. The figures generally show a counter-clockwise rotation and thus the torque is directed out of the page inFIG. 8(a).

In this last regard, it should be noted that if a force is allowed to act through a distance, it is doing mechanical work. Similarly, if torque (τ) is allowed to act through a rotational distance, it is doing work. Power (P) is the work per unit time. However, time and rotational distance are related by the angular velocity (ω) whereby each revolution results in the circumference of the circle being travelled by the force that is generating the torque.

The power (P) injected by the applied torque (τ) may be calculated as per the following relation:
P(t)=τ(t)·ω(t),
or perhaps more accurately in terms of fluid pressure (p) and fluid flow (Q), by the following relation:
P=p·Q

It should be noted that in the preferred embodiment, the convex surfaces20or convex surfacing of the vanes or blades11operate to deflect the fluid current100into the concave surfaces21of adjacent vanes or blades11such that the concave surfaces21capture deflected (as at104) fluid current100for increasing the first pressure relative to the second pressure and thus maximizing the torque as generally and comparatively depicted inFIGS. 7 and 8(a).

In this last regard, it is contemplated that the turbine assembly10may further preferably comprise bridge portions30, which bridge portions30extend intermediate adjacent vanes11for eliminating gaps between adjacent vanes11and/or for reducing drag on the assembly. In other words, the bridge portions30operate to direct deflected fluid current100from the convex surfaces20to the concave surfaces21such that the concave surfaces21may more readily capture the fluid current100.

The bridge portions30preferably connect the radially inner edges50to the convex outer surfaces20of adjacent vanes11such that the bride portions30and convex outer surfaces20of the vanes11enclose a transverse space as at115about the central shaft11. Together, the bridge portions30and convex outer surfacing20thus reduce drag between adjacent vanes.

Each vane or blade11further comprises a pointed inferior terminus as at22, a rounded superior terminus as at23, and sloped outer edges24extending intermediate the inferior and superior termini22and23. The superior termini23are preferably separated by a V-shaped gap25, which gap25essentially functions to reduce drag. In other words, fluid current100may escape surface capture via the gap(s)25, thereby reducing drag on the assembly10.

Each vane11further comprises a center of curvature as at40and a line of curvature as at41. The centers of curvature40are preferably located at the upper third of the concave surfaces21, and the lines of curvature41generally extending inwardly from the centers of curvature40towards the shaft12as generally and diagrammatically depicted inFIG. 10.

The vanes or blades11, so shaped and configured, essentially function to capture directed fluid current100intermediate a direction range (as at110) of the current100. In other words, fluid current100may be directed against the turbine from a variety of directions. These directions may be defined by a direction range110or range of current direction. The direction range110may be said to begin in or from the axial direction from the inferior terminus22(i.e. fluid current100may be axially directed into the vanes11via the inferior termini22).

It is contemplated that the upper limit106of the direction range110, the direction of fluid current100may extend 65 degrees (as at107) above the transverse plane (as at105) or 155 degrees from the axis of rotation101. It will thus be seen that while the preferred orientation of the turbine assembly10is vertical, it is also designed to capture fluid current100axially directed thereagainst (thus being capable of horizontal orientation) as well as downwardly angled fluid current100.

While the above description contains much specificity, this specificity should not be construed as limitations on the scope of the invention, but rather as an exemplification of the invention. For example, it is contemplated that the present invention essentially provides a turbine or rotor assembly for transferring energy from a fluid current100. The turbine or rotor assembly is contemplated to essentially comprise a central shaft12and at least two vanes11.

The shaft12is rotatable about an axis of rotation101, and the vanes are each attached to the shaft12. The vanes11each comprises a C-shaped cross section through a first plane as generally depicted inFIG. 8(a) and a J-shaped cross section through a second plane as generally depicted inFIG. 2(a). These cross sections are orthogonal to one another such that the scoop-like vanes11are generally shaped to resemble an inverted tear drop.

The cross sections each further have a convex surface (as at20) and a concave surface (as at21), which concave surfaces essentially function to capture a directed fluid current (as at100) and the convex surfaces essentially function to deflect said fluid current. The concave surfaces21and convex surfaces20are respectively associated with first and second current pressures whereby the first current pressure is greater than the second current pressure for imparting a net rotative force to the central shaft12for rotating the shaft12about the axis of rotation101.

The convex surfaces20preferably deflect the fluid current100into the concave surfaces21such that the concave surfaces21capture deflected fluid current100for increasing the first pressure relative to the second pressure, thereby maximizing the net rotative force. Bridge portions30preferably extend intermediate adjacent vanes11for reducing drag between adjacent vanes11, and preferably function to direct deflected fluid current100from the convex surfaces20to the concave surfaces21for capturing the fluid current.

Each vane preferably comprises a pointed inferior terminus22, a rounded superior terminus23, a sloped outer edge24extending intermediate the inferior and superior termini22and23, a center of curvature40located at the upper third of the concave surfaces21, and a line of curvature41extending inwardly from the center of curvature40towards the shaft12. The vanes11each function to capture directed fluid current intermediate a direction range110beginning in or from the axial direction from the inferior terminus and extending 155 degrees upwardly from the axial direction.

Further, the foregoing specifications are believed to support certain methodology for transferring energy from a fluid current. In this regard, the present invention is believed to support a method for transferring energy from a fluid current comprising the initial step of providing a turbine or rotor assembly having a shaft and a vane attached thereto. The shaft has an axis of rotation, and the vane has concave surfacing.

The concave surfacing has a J-shaped cross-section parallel to the axis of rotation and a C-shaped cross-section orthogonal to the axis of rotation. A fluid current is directed against and along the concave surfacing away from the shaft thereby creating a torque coaxial with the shaft for transferring energy from the fluid current.

The turbine assembly may preferably comprise at least two vanes each of which further have convex surfacing such that the method may comprise certain additional steps, including directing the fluid current against both the concave and convex surfacing, while directing the fluid current along the convex surfacing both toward and away from the shaft. A first current pressure is created at the concave surfacing and a second current pressure is created at the convex surfacing via the directed fluid current such that the first pressure is greater than the second pressure for enhancing or maintaining the torque.

The step of directing the fluid current along the convex surfacing toward the shaft may be further defined by comprising the step of directing the fluid current into the concave surfacing of adjacent vanes. Adjacent vanes may preferably comprise certain bridge means (as exemplified by bridge portions30) for bridge-directing the fluid current from the convex surfacing to the concave surfacing.

Accordingly, although the invention has been described by reference to certain preferred and alternative embodiments, and certain methodology, it is not intended that the novel disclosures herein presented be limited thereby, but that modifications thereof are intended to be included as falling within the broad scope and spirit of the foregoing disclosure, the following claims and the appended drawings.