JP2013519020A - Displacement structure for vertical axis wind power generator booster wing - Google Patents

Abstract

Displacement structure for a booster blade of a vertical axis wind power generator is provided.
A displacement structure includes a support device and a drive device. The support device is provided on a pedestal, and the support device is used for connecting booster blades, and is provided with a connection structure that is located outside the maximum rotational circumferential locus of the rotor blade of the wind power generator. In addition, the windbreak surface of the booster wing corresponds to some blades on the side of the rotor, which causes the booster wing to be part of the blades of the windward rotor where rotational resistance is created by the airflow that flows in use It is possible to block. The drive device is fixed to the pedestal and connected to the support device, so that the wind-shielding surface of the booster blade can block the other side surfaces of the rotor.
[Selection] Figure 1

Description

  The present invention provides a displacement structure for a vertical axis wind power generator assembly, in particular, a booster blade for a vertical axis wind power generator with a booster blade, as one of the fields of wind power generator technology.

  With existing technologies, the advantages of vertical axis wind generators such as high efficiency, high power, easy installation and use, and long service life are becoming increasingly significant. However, when the rotor rotates by receiving wind power, the rotational speed of the rotor does not increase in direct proportion to the increase in wind power. This phenomenon is even more apparent especially when wind power is not very strong. When receiving the airflow of the inflowing wind, the windward side receives a thrust that promotes the rotation of the rotor, and the opposite side receives a drag that stops the rotation of the rotor. It is effective power that the rotor rotates and works. However, there is wind resistance on the windward side, which clearly reduces the wind receiving performance of the vertical axis wind turbine rotor and the efficiency of the wind generator.

  In the existing technology, a method for solving the above-described problem is that a wind guide device is provided on the windward side of the rotor, and the wind is blown to the rotor via the flow channel of the guide device to promote the rotation of the rotor. To construct. Such a method of guiding natural wind to the guide channel and driving the moving blade to remove the wind resistance has a drawback of reducing the natural wind force. On the other hand, the natural wind direction can change frequently. For this reason, if the diversion device cannot change the diversion direction according to the wind direction, the loss of wind energy caused by the diversion device is further increased. If the diversion device is designed so that the diversion direction can be changed according to changes in the wind direction, the structure of the diversion device becomes complicated, making it difficult to use, manage, and maintain. The environment of power generation facilities is often severe.

  The present applicant has developed a technology capable of overcoming the wind resistance moment. According to this technique in which a booster blade is provided in front of the windward side of the rotor where a resistance moment is generated, the airflow to the moving blade can be stopped. If a part of this ventilation area is cut by the booster blade, the rotational performance of the rotor and the power generation capacity and power generation efficiency of the wind power generator will be clearly improved. Since the natural wind direction always changes, the position of the booster blade relative to the moving blade should also change according to the change in wind direction. In the case of strong wind, the ratio of the resistance moment to the effective propulsion moment generated in the rotor becomes very small. In this case, it is not necessary to provide a booster blade before the moving blade. At this time, the booster blade needs to be moved from the windward side of the rotor to the leeward side of the rotor, that is, downstream, or simply separated from the rotor.

  An object of the present invention is to provide a displacement structure of a booster blade of a vertical axis wind power generator, in which the position of the booster blade is easily changed and the structure is simple.

  The rotor of the vertical axis wind power generator is rotatably fixed to the central column of the vertical axis and is connected to the rotor of the generator unit. The rotor is provided with several blades, and the rotor includes a booster blade that is a wind shielding member having a wind shielding surface. The booster blade is provided in the support device and corresponds to one surface of the rotor of the vertical axis wind power generator. The one side is a part of the wind surface of the rotor in use. The rotor blade corresponding to this portion of the windward surface is prevented from rotating by the movement of the inflowing wind airflow, and this one face can be shielded by this booster blade.

  The said displacement structure which this invention provides can displace this support apparatus so that it may adapt to operation | movement of the rotor of a wind power generator.

  For this purpose, the displacement structure of the booster blade of the vertical axis wind power generator provided by the present invention includes a support device and a drive device. The support device is provided on a pedestal, and the support device is provided with a booster blade connection structure for connection to the booster blade so that the rotor of the vertical axis wind power generator does not rotate. ing. The windshield surface of the booster wing corresponds to the surface on one side of the rotor of the vertical axis wind power generator. The one surface is a part of the windward side when the rotor is used. The rotor blade that coincides with this portion of the wind surface is subjected to the action of rotational drag by the movement of the inflowing wind current, and this one surface is shielded by the booster blade.

  The drive device is fixed to the pedestal and connected to the support device, which displaces the support device to allow the booster blades to shield one side of the rotor.

  The support device is as follows. The support device includes two support rods, one end of which is connected to the upper end and the lower end of the booster wing via a connection structure, and the length thereof is determined by the booster wing. However, the other end of the two support rods is connected to the rotor of the wind power generator via a rotatable connection configuration. It is rotatably connected to a fixed central tower column, that is, a fixed base. The drive structure is connected to a connection structure that is rotatably connected to one central tower column of the support bar to rotate the support bar around the central tower column.

  The support device described above may be a bracket, and the bracket is provided with a booster blade fixing structure for providing the booster blade on the bracket. The support device is provided on a fixed pedestal formed by a foundation provided near the rotor of the vertical axis wind power generator, and the booster blade is positioned outside the rotational circumferential locus of the rotor blade. The drive device is attached to the bracket or the fixed base for driving the bracket to displace it relative to the foundation.

  A control device may be connected to a starting component of the drive device in order to perform opening / closing control of the drive device.

  The support rod has two portions, and the portion of the two portions close to the booster wing is a single support rod portion, one end of which is connected to the booster wing, and the other one portion is It is a double support rod part which has two 2nd support rods, The rotation connection structure for connecting with a central tower column rotatably is provided in the end. A T-connector is provided between the single support bar portion and the two second support bars, and three connecting parts are provided in a Y-shaped distribution on the T-connector, one on one side The connection part is connected to the other end of the single support bar part, and the two connection parts on the other side of the T-shaped connector are respectively connected to the other ends of the two second support bars.

  The connection structure between the support rod and the booster wing is as follows. The connection structure has one main connector with two holes, and the related end of the support bar or single support bar part is inserted and fixed in one of the holes, and the upper end of the booster wing Or the lower end is inserted and fixed in another hole.

  The support device further includes an oblique draw bar, one end of the oblique draw bar is provided with a connection structure fixed to the upper end of the booster blade, and the other end is rotatably connected to the central tower column. A connection structure is provided, and the position of the connection structure that connects the oblique drawbar and the central tower column is higher than the position of the connection structure that connects the support column connected to the upper end of the booster blade and the central tower column.

  A rotatable connection structure connecting the oblique drawbar to the central tower column is provided at the top of the central tower column.

  The rotatable connection structure that connects the oblique draw bar to the central tower column is a bearing device, and the inner ring and one of the outer rings that are relatively rotatable in the bearing device are connected to one end of the oblique draw bar. Therefore, the other end of the oblique draw bar is fixed to the main connector that connects the support bar and the upper end of the booster blade.

  The rotatable connection structure connecting the support rod to the central column is a bearing device, the outer sleeve is fixed to the outside of the outer ring of the bearing device, the outer sleeve is provided with a hole, and the end of the support rod The part is inserted into the hole and fixed.

  The cross section of the support bar is elliptical and the major axis of the elliptical cross section is provided in the horizontal direction, or the single support bar part and / or the cross section of the second support bar is elliptical. And the major axis of the elliptical cross section is provided in the horizontal direction and / or the cross section of the oblique drawbar is elliptical and the major axis of the elliptical cross section is provided in the horizontal direction.

  Preferably, the ratio of the minor axis to the major axis of the elliptical cross section of several support bars, single support bar sites and / or second support bars is in the range of 1/2 to 3/4.

  Preferably, the material of the support bar and the various parts is an aluminum mold or an aluminum member, and a light aluminum mold or a lightweight aluminum member is more preferable.

  The displacement structure of the booster blades of the vertical axis wind power generator provided by the present invention is a rational and simple structure, and can easily rotate the booster blades according to changes in wind direction and wind speed. The relative position of the machine to the rotor can be adjusted to increase the efficiency of the wind power generator.

It is a front view which shows the displacement structure of the booster wing | blade of the vertical axis wind power generator which this invention provides, and the rotor type booster wing | blade connected to it. FIG. 2 is a diagram showing an overhead view structure of FIG. FIG. 2 is a view showing the elevation structure of FIG. It is a figure which shows the bird's-eye view structure of the flat type booster blade provided in the rotor of a vertical axis wind power generator. It is a figure which shows the bird's-eye view structure of the rotor type | mold booster blade provided in the rotor of a vertical axis wind power generator. FIG. 6 is a view showing a front structure of a vertical axis wind power generator provided with the booster wing shown in FIG. 5; It is a figure which shows the structure of the main connector which connects a support rod and a booster wing | blade.

  The displacement structure of the booster blade of the vertical axis wind generator provided by the present invention is used with the following booster blade and the corresponding rotor of the vertical axis wind generator. As shown in FIGS. 5 and 6, the vertical axis wind power generator includes a vertical blade rotor 1 rotatably fixed on a central tower column 9 (shown in FIG. 1). Several blades 2 are provided on the rotor, and the blades 2 in the vertical blade rotor 1 are connected to the rotor hub by at least two support bars 5. The hub connected by at least one support rod is connected to the rotor of the power generation unit. The rotor hub that is not connected to the power generation unit is rotatably provided on the tower column 9. A stator corresponding to the rotor of the power generation unit is also fixed to the tower column 9. The shape of the blade 2 is a vertical columnar body, and its horizontal cross section exhibits the cross-sectional shape of an airplane wing, that is, corresponds to the rotational axis of the rotor, and its outer surface and windward surface transition smoothly. Streamlined arc surface, the spacing of the windward surfaces of the multiple blades is relatively large and gradually shrinks along the leeward direction, several horizontal sections of the columnar body are the same size, (Shown in FIGS. 5 and 6). Further, a booster blade is included, which may be a flat plate booster blade 2 ′ (see FIG. 4) or a rotor type booster blade 20 (see FIGS. 1, 5, and 6). There are connecting shafts at the upper and lower portions of the flat plate booster blade 2 ′, respectively, and the plate surface of the flat plate is a wind shielding surface.

  The rotor type booster blade may be a vertical rotor rotatably provided on the rotor shaft 5, and the rotor shaft 5 may be provided with a rotor 1 ′ (see FIG. 6), and a plurality of rotors 1 (see FIG. 1) may be provided. In the rotor 1 or 1 ′, the blade 23 is fixed to the connecting rod 3 via the hub 4, the hub 4 is arranged around the rotor shaft 5, and the bearing 6 is provided between the hub 4 and the rotor shaft 5. It is done.

  The rotor type booster blade is provided on the displacement structure of the booster blade. The displacement structure includes a support device and a drive device. A support device is provided on the pedestal, and the support device has a connection structure for connecting the booster blade to the outside of the maximum circumferential locus a (see FIG. 5) of the rotor blade of the wind power generator. The wind shield surface corresponds to a part of the blades 2 on the side surface of the rotor 1, and the booster blade in use can block the windward blade that receives the inflowing airflow. There, the rotation is hindered by airflow during operation. The drive device is fixed to the pedestal and connected to the support device, and by the displacement of the support device, the windshield surface of the booster wing can block another side surface of the rotor.

  Specifically, as shown in FIGS. 1, 2, 3, 4, 5, and 6, the upper and lower ends of the rotor shaft 5 of the booster blade rotor 1 are fixed to one end of two upper and lower support rods 21, respectively. The other end of the book is rotatably fixed to the central tower column 9, and the two support rods are provided at the upper and lower parts of the vertical rotor blade 2, respectively, and the booster blade is used as a wind shield to rotate the rotor blade. It is provided outside the circumferential trajectory a, so that it can be provided in front of the other wind surface of the low without disturbing the rotation of the rotor of the vertical axis wind generator. It blocks the windward side of the rotor and blocks the side of the vertical rotor of the wind generator. There, the rotational resistance is acted upon receiving the flowing air stream A. The drive structure is connected to one of the two support rods for connecting to the central tower column 9, that is, the above-mentioned fixed pedestal, thereby driving the support rod to rotate around the central tower column. And driving the rotation of the booster wing to change the relative position of the booster wing and the rotor, thereby adapting to changes in wind direction.

  The rotatable connection structure of the support rod 21 and the booster wing is as follows. As shown in FIG. 7, the main connector 2 has holes 201 and 202, and the end corresponding to the support rod 21 is inserted and fixed in one of the holes, and the upper end or lower end of the booster blade is connected to the other hole. Insert and fix.

  The connection structure for rotatably connecting the support rod and the central tower column is a bearing device. One of the inner ring and the outer ring that can rotate relative to the bearing device is a support rod, a large two support rods, Alternatively, it is connected to an oblique draw bar, and the other outer ring is fixed to the central tower column.

  In a specific embodiment, the support bar and the outer ring of the bearing are connected, the support bar and the bearing outer ring are connected by a support bar connector, and the support bar connector may be an outer sleeve provided outside the outer ring, A plurality of holes are formed in the outer sleeve, and the end of the support bar is inserted into the hole and fixed with screws.

  As shown in FIGS. 1, 2, and 3, the support rod may have two parts, a part close to the booster wing is a single bar part, and one end of the main connector is connected to the booster wing, The other part is a double part, such as two second support rods, for example, support rods 13 and 14 of the support rod fixed to the upper end of the booster wing, and support rods fixed to the lower end of the booster wing. Support rods 17 and 18 are provided. One end of the two support rods can also be fixed to the outer ring of the bearing 11 with the above structure, and the second support rods 13 and 14 are fixed to the outer ring of the bearing 11 with a support rod connector 15. 18 is fixed to the outer ring of the bearing 11 by a support rod connector 19, that is, two holes are made in the side wall corresponding to the support rod connectors 15 and 19, and two second support rods of one support rod are formed. Both ends are inserted and fixed, and in this manner, a rotatable connection with the central tower column can be realized. T-connectors 12 and 16 are provided between the single support rod portion and the two second support rods, and three connection portions having a Y-shaped distribution are provided on the T-connector connector, One connection portion is connected to the other end of the single support rod portion, and two connection portions provided on the other end side of the T-shaped connector are respectively connected to the other end portions of the two second support rods. The

  The support rod having the two second support rods can resolve the gravity and the drag received by itself, and the strength and rigidity of the structure is stronger than the support rod of the single support rod. In order to further reduce the drag of the rotor, the support rod can be made thinner.

  As shown in FIG. 1, a driver 10 for driving the rotation of the outer ring of the bearing can be connected to the outer ring of the bearing connected to the upper support rod. The driver is provided and fixed in a hollow central column. The driver is. An electric motor may be used. The output shaft of the electric motor is connected to the outer ring of the bearing. The electric energy input of the electric motor can be connected to the power grid. Moreover, the electrical storage structure provided in a wind power generator can also be connected. The power storage structure may obtain power from a wind power generator. A power generation unit may be provided between the rotor of the rotor type booster blade and the rotor shaft. Further, it may be used as a generator while being used as a booster blade for shielding the blade, and the generated electric energy may be stored in the power storage structure, thereby driving the rotation of the booster blade.

  The support device is provided with an oblique draw bar, one end of which is provided with a connection structure that is fixed to the upper end of the booster blade, and the other end thereof is provided with a rotatable connection structure that is rotatably connected to the central tower column. It is done. The position of the connection structure for connecting the oblique draw bar and the central tower column is higher than the position of the connection structure for connecting the support rod connected to the upper end of the booster blade and the central tower column.

  As shown in detail in FIGS. 1 and 6, a reinforcing rib 203 (see FIG. 7) is provided on the upper portion of the main connector 2 connected to the upper end of the rotor shaft 5 of the booster blade 1. Is provided with a connection structure for fixing one end of the oblique draw bar 7. The other end of the oblique draw bar 7 extends obliquely upward to the central tower column 9 and is connected to an oblique draw bar bearing 8 at the top of the tower column 9 for forming a connection structure rotatably connected to the tower column 9. . The slanted drawbar makes the connection between the booster wing and the central tower column even stronger.

  The material of each support bar, main connector, T-shaped connector, support bar connector, etc. in the support device is an aluminum mold or an aluminum product. A support device made of a light aluminum mold has the advantages of light weight and low drag.

  The preferred cross-sectional shape of the various bodies of the support rod, or the single support rod portion or the two-part type support rod of the second support rod is an ellipse, and the major axis of the ellipse is in the horizontal direction. Is provided.

  The cross section of the oblique draw bar may also be elliptical, and its long axis may be provided in the horizontal direction.

  The ratio of the minor axis to the major axis of the elliptical cross section of the various support rods is 1/2 to 3/4.

  Each bearing provided in the central column may be a standard part, or may be a different type of rolling bearing, such as a roller bearing.

  A control device may be connected to a starting component of the drive device in order to perform opening / closing control of the drive device. This mechanism transmits a signal to the controller according to the wind direction indicator. The wind direction indicator sequentially gives commands to the driver, and the rotation mechanism of the booster wing rotates in synchronization with the windward or leeward side, or rotates to the new windward side of the rotor when the wind direction changes Make it possible to do. This controller may utilize a PLC controller M340.

  The booster wing may be connected to the central tower column or may be connected to a fixed bracket near the wind power generator. For example, a track is provided on the ground other than the rotor of the wind power generator, a bracket is movably installed on the track, a plate or a rotor type booster blade is fixed to the bracket, and the relative positional relationship with respect to the rotor blade is as described above. It may be the same as the street, and this can stop the wind caused by the rotation of the rotor from flowing into the rotor blades. The bracket is provided with a plurality of wheels, which are connected to a drive structure, and a brake device is provided in the drive structure. When the drive structure is activated, the bracket can be moved along the track. In the case of a brake, it can brake with the brake device provided in a drive structure.

  Since there are too many devices capable of fixing and displacing the booster blade, only the above embodiment has been described, but the above embodiment does not limit the present invention.

  The structure of the booster blade displacement of the vertical axis wind generator provided by the present invention is used to change the booster blade position of the vertical axis wind generator.

1 ... Booster wing 1 ... Vertical blade rotor (Booster wing rotor)
2 ... Vertical rotor blade 2 ... Flat type booster blade 2 ... Main connector 3 ... Connecting rod 4 ... Hub 5 ... Support rod 5 ... Rotor shaft 6 ... Bearing 7 ... Diagonal draw bar 8 ... Diagonal draw bar bearing 9 ... Central tower column 10 ... Drive Device 11 ... Bearing 13 ... Second support rod 15 ... Support rod connector 17 ... Support rod 19 ... Support rod connector 20 ... Rotor booster blade 21 ... Support rod 23 ... Blade 201 ... Hole 203 ... Reinforcement rib

Claims (10)

Displacement structure of booster wing of vertical axis wind generator,
A support device and a drive device;
The support device is provided on a pedestal;
In the support device, the connection structure of the booster blade used for connection of the booster blade is provided in a mode that does not hinder the rotation of the rotor of the vertical axis wind power generator,
The windshield surface of the booster wing corresponds to the side surface of the rotor of the vertical axis wind power generator,
The side surface is a part of the windward side of the rotor in use,
The booster wing corresponding to the part of the wind surface receives rotational resistance due to the inflowing airflow,
The booster wing is configured to be able to block the side surface,
The drive device is disposed on the pedestal and is connected to the support device so as to displace the support device so that the wind-shielding surface of the booster blade can block the other side surfaces of the rotor. The displacement structure of the booster wing of the configured vertical axis wind power generator. The displacement structure of the booster blade of the vertical axis wind power generator according to claim 1,
The support device has two support rods;
One end of each of the two support rods is connected to the upper end and the lower end of the booster wing by the connection structure,
The lengths of the two support rods are formed such that the booster blades are located outside the maximum rotational circumferential locus of the rotor blade of the wind power generator,
The other ends of the two support rods are rotatably connected to a fixed central tower column of the rotor of the wind power generator, that is, the fixed base, by a rotatable connection structure,
A driving device connected to the connection structure rotatably connected to the central column of one of the support rods to drive the support rod and rotate around the central column; Or
The support device is a bracket;
The bracket is provided with a fixing structure for the booster wing so that the booster wing structure is provided on the bracket,
The support device is provided on the fixed base formed by a foundation provided near the rotor of the vertical axis wind power generator, and the booster blade is positioned outside the rotational circumferential locus of the rotor blade. Let
The drive device is attached to the bracket or the fixed base in order to drive the bracket and displace it with respect to the foundation, or
A displacement structure of a booster blade of a vertical axis wind power generator connected to a starting component of the drive device so that the control device performs opening / closing control of the drive device. The displacement structure of the booster blade of the vertical axis wind power generator according to claim 1,
The support bar has two parts,
Of the two parts, the part close to the booster wing is a single support bar part,
One end of the single support rod part is connected to the booster wing,
The other part is a double support bar part with two second support bars,
One end of the two second support rods is provided with the rotatable connection structure for rotatably connecting to the central tower column,
A T-connector is provided between the single support bar portion and the two second support bars;
Three connecting components are provided in the T-shaped connector in a Y-shaped distribution,
One connecting piece on one side connects to the other end of the single support bar part;
The two connecting parts on the other side of the T-shaped connector are each a displacement structure of a booster blade of a vertical axis wind power generator connected to the other end of the two second support rods. A displacement structure of a booster blade of a vertical axis wind power generator according to claim 2 or 3,
The connection structure between the support bar and the booster wing has one main connector provided with two holes, and the related end of the support bar or the single support bar part is: A displacement structure of a booster blade of a vertical axis wind power generator, which is inserted and fixed in one of the holes, and an upper end or a lower end of the booster blade is inserted and fixed in another hole. A displacement structure of a booster blade of a vertical axis wind power generator according to claim 2 or 3,
The support device further includes an oblique draw bar,
One end of the oblique drawbar is provided with a connection structure fixed to the upper end of the booster wing,
The other end is provided with a rotatable connection structure that is rotatably connected to the central tower column,
The position of the connection structure that connects the oblique draw bar and the central tower column is higher than the position of the connection structure that connects the support rod connected to the upper end of the booster blade and the central tower column. Displacement structure of booster wing of axial wind generator. A displacement structure of a booster blade of a vertical axis wind power generator according to claim 5,
The rotatable connection structure connecting the oblique draw bar to the central tower column is a bearing device;
An inner ring and one of the outer rings relatively rotatable in the bearing device are connected to the central tower column in a state where the other is used to connect to one end of the oblique draw bar,
A displacement structure of a booster blade of a vertical axis wind power generator, wherein the other end of the oblique drawbar is fixed to a main connector connecting the support rod and the upper end of the booster blade. A displacement structure of a booster blade of a vertical axis wind power generator according to claim 2,
The rotatable connection structure for connecting the support rod to the central tower column is a bearing device;
An outer sleeve is fixed to the outer side of the outer ring of the bearing device;
The outer sleeve is provided with a hole,
An end portion of the support bar is a displacement structure of a booster blade of a vertical axis wind power generator inserted and fixed in the hole. A displacement structure of a booster blade of a vertical axis wind power generator according to claim 3,
The rotatable connection structure that connects the two second support rods of the support rod to the central tower column is a bearing device;
An outer sleeve is fixed to the outer side of the outer ring,
The outer sleeve is provided with two holes,
The end portions of the two support rods are inserted into the two holes and fixed, and the displacement structure of a booster blade of a vertical axis wind power generator. The displacement structure of the booster blade of the vertical axis wind power generator according to any one of claims 2, 3, 5, and 6,
The cross section of the support rod is elliptical, and the major axis of the elliptical cross section is provided in the horizontal direction, or
The cross section of the single support bar portion and / or the second support bar is elliptical, the major axis of the elliptical cross section is provided in the horizontal direction, and / or
The cross section of the oblique draw bar is elliptical, and the major axis of the elliptical cross section is provided in the horizontal direction, or
The support device is made of an aluminum mold or an aluminum member. A displacement structure of a booster blade of a vertical axis wind power generator. A displacement structure of a booster blade of a vertical axis wind power generator according to claim 9,
The ratio of the minor axis to the major axis of the elliptical cross section of the several support rods is 1/2 to 3/4. The displacement structure of the booster blade of the vertical axis wind power generator.

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