JP2013532796A - Screw turbine and power generation method - Google Patents

Abstract

A screw turbine that provides improved efficiency under certain conditions compared to existing hydro turbine examples.
A spiral turbine blade mounted for axial rotation, a mount associated with the spiral turbine blade for mounting for axial rotation, and energy imparted to the spiral turbine blade for power. A screw turbine comprising a generator associated with the helical turbine blade, wherein the helical turbine blade has a shorter diameter than the lead of the helical turbine blade and allows lateral exchange of fluid in use Constructed, screw turbine.
[Selection] Figure 1

Description

  The present invention relates to a screw turbine and a power generation method using the screw turbine. In particular, the invention relates to an Archimedes screw turbine having a helical turbine blade that has a relatively small helix angle and advantageously does not require or utilize an outer coating that accommodates it in use.

  Various forms of turbines are known. These include, for example, crossflow turbines, Kaplan turbines, and Archimedes screw turbines.

  In a crossflow turbine, a cylindrical water wheel or impeller having a horizontal shaft is provided. The water wheel or impeller includes a plurality of blades arranged in a radial direction and a tangential direction. The blade edge may be sharpened to reduce resistance to water flow. Unlike most hydro turbines that have axial or radial flow, in a cross-flow turbine, water passes across the turbine, i.e., across the turbine blades. Like a water wheel, water is taken up at the edge of the turbine. The water leaves the opposite side after passing through the impeller. Passing the impeller twice provides additional efficiency. Water also helps remove small debris and dirt on the impeller as it leaves the impeller. A cross-flow turbine is a low speed machine that is well suited for low head but high flow rates.

  A Kaplan turbine is a propeller hydro turbine with adjustable blades. The Kaplan turbine was developed in 1913 by Victor Kaplan. This person combined self-adjusting propeller blades and self-adjusting guide vanes to gain efficiency over a wide range of flows and water levels. The Kaplan turbine is an inward flow reaction turbine. Thus, the working fluid changes pressure and passes its energy as it passes through the turbine. The design combines radial and axial features.

  The Archimedes screw turbine was developed on the basis of the Archimedes screw pump principle. Archimedes screw pumps are a form of water pump that has been known for centuries. In order to pump from bottom to top, the pump needs to be turned manually or through some other mechanism such as a windmill. The Archimedes screw turbine is basically an inverse of the Archimedes screw pump and uses water to drive the screws and to convert energy through the generator.

  A major advantage of these turbines over other turbines used in small hydropower schemes is that they work well even with low heads. Thus, these turbines can be used on existing weirs or in effluent pipes and generally do not require large amounts of piping to make the civil engineering components of the scheme finer. Garbage in the river simply passes (at least to some extent) and does not require a dust screen.

  The efficiency of turbines, especially wind turbines, is predicted by Betz's law. This law is the theory of the maximum possible energy that can be obtained from the hydraulic wind engine, developed in 1919 by the German physicist Albert Betz. According to this law, no turbine can obtain more than 59.3% of the kinetic energy of the wind. That is, the more gears are attached to the propeller that resists the wind to generate more force, the slower the propeller and the less force is generated. Although Betz's law can be applied to hydro turbines as well, it is believed that there are several additional factors that affect this situation. Specifically, since water is not compressible, it is believed that a hydro turbine can achieve higher efficiency than a wind turbine. Thus, in addition to the kinetic energy of water, some energy can be applied in the form of pressure. Nevertheless, the efficiency that can be obtained using existing hydro turbines is limited.

  The present invention aims to provide an alternative form of hydro turbine in the form of an Archimedes screw turbine that can provide improved efficiency under certain conditions compared to existing hydro turbine examples.

According to one aspect of the invention,
A spiral turbine blade mounted for axial rotation;
A mount associated with and attached to the spiral turbine blade for axial rotation;
A generator associated with the spiral turbine blade that converts the energy imparted to the spiral turbine blade into electrical power;
A screw turbine comprising:
A screw turbine is provided in which the diameter of the spiral turbine blade is shorter than the lead of the spiral turbine blade and is configured to allow lateral exchange of fluids in use.

  As used herein, the term “lead” is intended to mean the distance between successive contours of a helical turbine blade, measured parallel to the blade axis. This is identified as distance “b” in FIG.

  As used herein, the term “lateral exchange” means that fluid that has lost energy (ie, slowed down) due to transmission to the rotation of a helical turbine blade is replaced by fluid with higher energy. As such, it is intended to mean that it is emitted radially from the helical turbine blade. For example, if the screw turbine is submerged in running water, the water that has transferred energy to the rotation of the helical turbine blade (i.e. slowed down) can be released radially and replaced with faster flowing water. .

  It is believed that the screw turbine of the present invention can provide surprisingly good results, especially in applications involving low flow rates. It is believed that the screw turbine of the present invention can provide a proportional increase or close to the generated force as the length of the helical turbine blade increases. That is, it may be possible to provide a turbine that overcomes the historically considered Betz limit associated with such systems.

  In a preferred embodiment, the screw turbine's helical turbine blades are exposed in use to allow lateral exchange of fluids. This also provides sufficient spacing between the spiral turbine blade and the surrounding outer coating, or sufficient vents in such an outer coating so that fluid can be discharged radially. It is assumed that this can be achieved by providing.

  The relationship between the diameter of the spiral turbine blade and the lead is not particularly limited. However, the diameter of the spiral turbine blade is shorter than the lead of the spiral turbine blade. That is, the “twist” of the spiral turbine blade is relatively gradual. In a preferred embodiment, the spiral turbine blade diameter to lead ratio is about 1: 8.

  The helical turbine blade may preferably have a lead angle of 50 ° to 75 °, such as a lead angle of about 60 ° to 75 °. However, in certain embodiments, the lead angle can be as high as 80 °. Such an angle, in concert with a relatively small helix angle, results in a relatively gentle twist in the blade.

  In one particular preferred embodiment for facilitating the lateral exchange of fluids, the helical turbine blade is an axleless helix. Nevertheless, it is believed that a spiral turbine blade with a shaft may also be useful according to the present invention.

  As used herein, the term “axisless spiral” refers to the length of a blade without a central axis around which the blade is mounted (i.e., similar to a conventional Archimedes screw pump). Is intended to mean composed of a piece of material twisted along. This is best illustrated in FIGS. 2 and 3.

  The helical turbine blade can be attached by any suitable means. For example, the blade may be mounted on a structure constructed in the water body (i.e., fixed in the river bed) or, for example, fixed to and extending from a river bank or shore It may be attached to the distal end of the arm. The form of attachment will depend to some extent on the particular environment involved. The blade must be mounted for rotation, for example, via a joint provided with a bearing that facilitates rotation of the blade about its longitudinal axis.

  The spiral turbine blade can be connected to the generator in the usual manner. For example, a drive shaft associated with the blade may be engaged with a gear device that engages a generator for generating electrical power. In such cases, it may be preferred that the gearing operate at low revs and high torque. That is, a relatively high gear ratio will be preferred. This gear ratio can depend on the individual use environment.

  In accordance with another aspect of the present invention, there is provided a helical turbine blade for a screw turbine comprising an axisless spiral, the diameter of the axisless spiral being shorter than the lead of the axisless spiral. .

  As with the previous embodiment of the present invention, the ratio of the spiral turbine blade diameter to lead is preferably about 1: 8. The helical turbine blade preferably has a lead angle of 50 ° to 75 °, for example a lead angle of about 60 ° to 75 °, but can be as high as 80 °.

  The spiral turbine blade may be formed from any suitable material, for example, steel or equivalent material. The helical turbine blade may be formed from a composite material.

According to a further aspect of the invention,
Sinking a screw turbine provided with a spiral turbine blade into a flowing water body;
Converting energy imparted to the spiral turbine blade into mechanical power or power, comprising:
A power generation method is provided in which the screw turbine is configured to allow lateral exchange of water when the spiral turbine blade is rotated by running water.

  The screw turbine is preferably exposed and submerged to allow for lateral exchange of water when the spiral turbine blade is rotated by running water. Other possible embodiments have been disclosed above, but are not considered preferred.

  In general, the energy imparted to the spiral turbine blade is converted into electric power through a generator. However, in certain embodiments it is envisioned that energy is converted to mechanical energy and used for other purposes.

  As with other aspects of the invention, the diameter of the helical turbine blade is typically shorter than the lead of the helical turbine blade. For example, a helical turbine blade can include an axisless spiral, the diameter of the axisless spiral being shorter than the lead of the axisless spiral.

  Again, the spiral turbine blade diameter to lead ratio is preferably about 1: 8. The helical turbine blade may have a lead angle of about 50 ° to 75 °, such as a lead angle of about 60 ° to 75 °.

  The present invention will now be described in more detail with reference to the accompanying drawings. It should be understood that the following are given by way of example only and should not be construed as limiting the invention in any way.

2 is a side view of a spiral turbine blade. FIG. 1 is a perspective view of a spiral turbine blade. FIG. 1 is a perspective view of a spiral turbine blade. FIG.

  Referring to the figures, the spiral turbine blade takes the form of an axisless spiral. In effect, a helical turbine blade is composed of a piece of material, eg, steel or other suitable material, twisted along its length. The twist is relatively gradual, and therefore the helix angle γ is relatively small. As a result, the lead angle α is relatively large. This is especially true when compared to conventional screw turbines, where the blades are generally provided with a much greater slope.

  The diameter “a” of the spiral turbine blade is shorter than the lead “b” of the blade. As illustrated, the ratio of diameter to lead is just over 1: 8. It is considered that this configuration, combined with the removal of the shaft, facilitates better lateral exchange of the fluid during use.

  In general, helical turbine blades are submerged in running water without any coating. Referring to the figure, by doing so, the water powers the blade to force the blade to rotate, losing energy and speed, and radiating from the blade allowing faster water to replace it. It will be understood that Thus, it is assumed that as the length of the helical turbine blade increases, the force generated increases proportionally.

  Spiral turbine blades and screw turbines utilizing them are believed to be useful in slow flow rivers and other relatively small flow environments. For example, a screw turbine may be a viable alternative to a proposed hydropower plan for the Amazon River. Taking this example, the present invention has the ability to provide power while maintaining the tribal land threatened by the proposed plan (i.e., building a series of giant dams throughout the Amazon Basin). It can provide significant advantages including.

  Due to the fact that the spiral angle is small (as opposed to a propeller), the spiral turbine blade does not rotate rapidly or aggressively and therefore operates with relatively low efficiency. However, due to the possibility of being longer than is commonly found in existing turbines, the medium (i.e. water) has the opportunity to act on a relatively large surface area and thereby the force transmitted to rotation. The total amount of is increased.

  Unless otherwise required by context or explicitly stated to the contrary, the integers, steps, or configurations of the invention cited herein as a single integer, step, or element An element explicitly includes the quoted integers, steps, or both singular and plural forms of the element.

  Throughout this specification, unless otherwise required by context, the word “comprise” or “comprises” or “including” is provided. Variations such as “comprising” are meant to include the stated step or element or integer, or a group of steps or elements or integers, but any other step or element or integer, or step or element or integer. It will be understood that it is not meant to exclude the group. Thus, in the context of this specification, the term “comprising” is used in a comprehensive sense, and thus “mainly includes, but does not necessarily include only. It should be understood as meaning "not."

  The foregoing description has been given by way of illustration to serve to illustrate the invention, and all such modifications and variations have been described herein which will be apparent to those skilled in the art. It will be understood that they are considered to fall within the broad scope and boundaries of the present invention.

Claims (16)

A spiral turbine blade mounted for axial rotation;
A mount associated with the helical turbine blade and mounted for axial rotation of the helical turbine blade;
A generator associated with the helical turbine blade that converts energy imparted to the helical turbine blade into electrical power;
A screw turbine comprising:
A screw turbine configured such that the diameter of the spiral turbine blade is shorter than the lead of the spiral turbine blade and allows lateral exchange of fluids in use.   The screw turbine of claim 1, wherein the helical turbine blade of the screw turbine is exposed in use to allow lateral exchange of fluid.   The screw turbine according to claim 1 or 2, wherein a ratio of a diameter and a lead of the spiral turbine blade is 1: 8.   4. A screw turbine according to any one of the preceding claims, wherein the helical turbine blade has a lead angle of about 50 ° to 75 °, such as a lead angle of about 60 ° to 75 °.   5. The screw turbine according to claim 1, wherein the helical turbine blade is a non-axial spiral body.   6. The screw turbine according to any one of claims 1 to 5, wherein the at least one mounting base comprises a joint provided with a bearing that facilitates rotation of the helical turbine blade about a longitudinal axis.   A drive shaft associated with the blade is engaged with a gearing that engages the generator for generating power, the gearing preferably operating at low revs and high torque. The screw turbine according to any one of claims 1 to 6.   A helical turbine blade for a screw turbine, comprising an axis helix, wherein the diameter of the axis helix is shorter than a lead of the axis helix.   9. The spiral turbine blade of claim 8, wherein the spiral turbine blade diameter to lead ratio is 1: 8.   10. A helical turbine blade according to claim 8 or claim 9, wherein the helical turbine blade has a lead angle of about 50 ° to 75 °, such as a lead angle of about 60 ° to 75 °. Sinking a screw turbine provided with a spiral turbine blade into a flowing water body;
Converting the energy imparted to the helical turbine blade into mechanical power or electric power,
The power generation method, wherein the screw turbine is configured to allow lateral exchange of water when the spiral turbine blade is rotated by the flowing water.   12. The power generation method according to claim 11, wherein the screw turbine is exposed and submerged to allow lateral exchange of water when the spiral turbine blade is rotated by the flowing water.   The power generation method according to claim 11 or 12, wherein the energy applied to the spiral turbine blade is converted into electric power through a generator.   The diameter of the helical turbine blade is shorter than the lead of the helical turbine blade, preferably the helical turbine blade comprises an axis helix, and the diameter of the axis helix is shorter than the lead of the axis helix. The power generation method according to any one of claims 11 to 13.   15. The power generation method according to any one of claims 11 to 14, wherein the spiral turbine blade diameter to lead ratio is about 1: 8.   16. The power generation method according to any one of claims 11 to 15, wherein the helical turbine blade has a lead angle of about 50 ° to 75 °, for example a lead angle of about 60 ° to 75 °.

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