JP4909578B2 - Windmill drive - Google Patents

Description

  The present invention relates to a windmill drive device used to change the direction of a nacelle or blade of a wind power generator.

  Conventionally, a wind turbine driving device such as a nacelle driving device used to change the direction of a nacelle of a wind power generator is known (see, for example, Patent Document 1).

The conventional wind turbine driving device disclosed in Patent Document 1 is provided at the upper part of a tower standing on the ground, and the direction of the nacelle rotatably supported on the upper part of the tower is changed. It is configured. That is, an internal gear is provided in the upper portion of the tower, and an external gear (pinion) connected to an output shaft that rotates as the motor is driven meshes with the internal gear. In this conventional wind turbine driving apparatus, the external gear is rotated while meshing with the internal gear by rotating the output shaft, thereby changing the direction of the nacelle. The external gear is coupled to the output shaft in a state of being fitted around the end of the output shaft.
Japanese Patent Laid-Open No. 2004-232500

  In the conventional wind turbine driving device disclosed in Patent Document 1, the external gear is coupled to the output shaft in a state of being externally fitted to the end of the output shaft. There is a spline connection as a connection method. That is, in this spline coupling, the spline hole formed in the central portion of the external gear is externally fitted and coupled to the spline portion formed on the peripheral surface of the output shaft.

  However, in such a spline connection, there is a case where some rattling occurs in the joint portion. Therefore, when an impact or vibration due to a gust or the like is transmitted, the external gear is caused by the rattling. In addition, the spline joint of the output shaft is damaged or worn. As a result, there is a problem that the life of the external gear and the output shaft is shortened.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a windmill drive device capable of extending the life of the external gear and the output shaft.

In order to achieve the above object, a wind turbine driving device according to the present invention includes a first member made of a nacelle or a blade that is supported so as to be rotatable relative to a second member that supports the first member. An internal gear is provided on one of the member and the second member, and an external gear that meshes with the internal gear is provided on a carrier that is rotated by a reduction mechanism , and the carrier rotates with respect to the second member. A windmill drive device that relatively changes the direction of the first member, and the external gear includes a tooth portion that meshes with the internal gear and a shaft portion that is integrally formed with the tooth portion, This shaft portion is fixed to the carrier .

In this windmill drive device, the tooth portion and the shaft portion of the external gear are integrally formed, and the shaft portion is fixed to the carrier. Even when vibration is transmitted, the external gear and the carrier can be prevented from being damaged or worn. In other words, when the carrier and the external gear are connected by spline connection, the external tooth is generated when shock or vibration is transmitted from the nacelle or blade due to the gust due to rattling at the spline connection part. The spline joint of the gear and carrier can be damaged or worn. However, in the wind turbine driving device of the present invention, such a spline coupling portion does not exist, the tooth portion of the external gear and the shaft portion are integrally formed, and the shaft portion and the carrier are fixed. Therefore, rattling does not occur between the shaft portion of the external gear and the carrier . For this reason, the inconvenience that the external gear and the carrier are damaged or worn by the rattling as described above does not occur. As a result, in the wind turbine driving device of the present invention, the life of the external gear and the carrier can be extended.

In the above wind turbine drive apparatus, the shaft portion of the external gear and one of the carrier has a male threaded portion, the shaft portion and the other of the carrier of the external gear has a female thread portion screwed to the male screw portion It is preferable. If comprised in this way, the drive device for windmills which has a structure which adhere | attaches the axial part and carrier of an external gear can be manufactured easily.

In the wind turbine driving device, the speed reduction mechanism includes an eccentric rotation gear that rotates eccentrically as the input shaft rotates by driving the motor, and is coupled to the carrier . The eccentric rotation gear includes a hole portion. The carrier is inserted in a state where there is a gap in the hole, and the carrier is rotated along with the eccentric rotation of the eccentric rotation gear. The width of the gap between the carrier and the carrier is preferably larger than the amount of movement of the carrier in the hole when vibration is transmitted from the first member to the carrier . According to this structure, since no carrier is in contact with the hole of the eccentric rotation gear when the vibration from the first member to the carrier is transmitted, suppressing the transmission of vibration to the wear and the speed reduction mechanism of the carrier be able to.

As described above, according to the present invention, damage or wear of the external gear and the carrier due to impact or vibration can be suppressed, so that the life of the external gear and the carrier can be extended.

  Hereinafter, the best mode for carrying out the present invention will be described in detail with reference to the drawings. In the following description of the embodiment, a pitch driving device used to change the direction of the blade will be described as an example of the wind turbine driving device according to the present invention.

  FIG. 1 is a perspective view showing a main part of a wind power generator 1 to which a pitch driving device 10 according to an embodiment of the present invention is applied. FIG. 2 is a view showing a joint between the hub 5 and the blade 6 of the wind power generator 1 shown in FIG. 1 and the pitch driving device 10 installed there. 3 is a cross-sectional view showing the overall configuration of the pitch driving device 10 shown in FIG. 2, and FIG. 4 is a view of the pitch driving device 10 shown in FIG. 3 as viewed from the direction of arrow IV in FIG. . FIG. 5 is a cross-sectional view taken along line VV of the pitch driving device 10 shown in FIG. First, with reference to FIGS. 1-5, the structure of the pitch drive device 10 by one Embodiment of this invention and the wind power generator 1 using the same is demonstrated.

  As shown in FIG. 1, the wind power generator 1 according to the present embodiment includes a support column 2 erected on the ground and a nacelle 3 supported on the upper end of the support column 2 so as to be relatively rotatable. The nacelle 3 houses a gear box, a generator, etc. (not shown). The nacelle 3 is provided with a rotor connected to a gear box, and a plurality of blades 6 (first member) are supported by a hub 5 (second member) of the rotor so as to be relatively rotatable. Note that FIG. 1 shows a configuration in which three blades 6 are provided.

  As shown in FIG. 2, the blade 6 is supported by the hub 5 via a bearing 8 and can be rotated around the axis of the blade 6. A support portion 5a formed in an annular shape is provided on the inner surface of the hub 5, and the pitch drive device 10 according to the present embodiment can be supported by the support portion 5a.

  The blade 6 is provided with a ring gear 7 (internal gear) at its base end. An output shaft gear 23 (external gear) of the pitch driving device 10 described later meshes with the ring gear 7 and is used to turn the blade 6 in the axial direction to change the direction. Hereinafter, the configuration of the pitch driving device 10 will be specifically described.

  As shown in FIG. 3, the pitch driving device 10 includes a bottomed cylindrical outer case 12. The outer case 12 is configured by fastening a cylindrical portion 13 formed in a cylindrical shape and a cover 14 formed in a bottomed cylindrical shape. The cylindrical portion 13 is provided with a flange portion 13a for attachment to the support portion 5a of the hub 5, and can be fastened to the support portion 5a by a bolt 15 through the flange portion 13a. A drive motor 16 (motor) is fixed to the bottom surface of the cover 14.

  A large number of internal teeth pins 18 are fixed to the inner peripheral portion of the cylindrical portion 13 in the axially intermediate portion. The internal tooth pins 18 are arranged in a posture extending in the axial direction, and these are arranged at equal intervals in the circumferential direction. Each internal tooth pin 18 constitutes an internal tooth of an internal gear.

  The pitch driving device 10 includes an input shaft 21, a carrier 22, an output shaft gear 23 (external gear), and a speed reduction mechanism 24. The carrier 22 is disposed so as to be rotatable about the same axis as the axis of the input shaft 21. The pitch driving device 10 can be arranged so that the drive motor 16 is located on the hub 5 side and the carrier 22 is on the blade 6 side. Therefore, in the following description, the blade 6 side is aligned with FIGS. The upper side and the hub 5 side will be described as the lower side.

  A drive shaft (not shown) of the drive motor 16 extends upward from the drive motor 16 and penetrates the central portion of the cover 14. This drive shaft is rotatable with respect to the cover 14 by a bearing (not shown). The drive shaft is connected to the input shaft 21, and the input shaft 21 is rotated by applying a rotational driving force of the drive motor 16 to the input shaft 21. A driving external gear 21 a is provided at the upper end of the input shaft 21.

  The carrier 22 is disposed on the radially inner side of the cylindrical portion 13. The carrier 22 and the output shaft gear 23 are rotatably supported with respect to the cylindrical portion 13 by bearings 32 and 33 disposed at two locations in the axial direction. The axis of the carrier 22 coincides with the axis of the cylindrical portion 13. The carrier 22 includes a base portion 35 (output shaft), an end plate portion 36 disposed below the base portion 35, and a shaft portion 37 that is a part of the base portion 35.

  The shaft portion 37 is divided into a base side shaft portion 41 provided in the base portion 35 and an end plate side shaft portion 42 provided in the end plate portion 36. Three shaft portions 37 composed of the base portion side shaft portion 41 and the end plate side shaft portion 42 are provided (see FIG. 5) and are arranged at equal intervals in the circumferential direction. Each shaft portion 37 is formed in a substantially triangular cross section. The base side shaft portion 41 is configured in a column shape extending in the axial direction downward from the lower surface of the base portion 35, and the end plate side shaft portion 42 is formed in a column shape extending in the axial direction upward from the upper surface of the end plate portion 36. It is configured. The base portion side shaft portion 41 and the end plate side shaft portion 42 are provided at positions facing each other.

  The base side shaft portion 41 is provided with a bottomed bolt hole, and the end plate side shaft portion 42 is provided with a bolt insertion hole at a position corresponding to the bolt hole. The bolts 43 inserted through these bolt insertion holes are screwed into the bolt holes of the base side shaft portion 41. Further, the base side shaft portion 41 and the end plate side shaft portion 42 are fitted with a spigot. Further, the base side shaft portion 41 and the end plate side shaft portion 42 are respectively provided with pin holes, and pins 44 (see FIG. 5) are inserted so as to straddle these pin holes. Thus, the base portion 35 and the end plate portion 36 are fixed so as not to be displaced from each other.

  In the present embodiment, the output shaft gear 23 (external gear) is configured by an external tooth portion 23a (tooth portion) (see FIG. 4) and a shaft portion 23b formed integrally with the external tooth portion 23a. The shaft portion 23 b is fixed to the base portion 35. Specifically, the base part 35 has a bolt 35a (male thread part) provided so as to protrude upward at a position corresponding to the axial center of the upper surface. The bolt 35 a is inserted from below into a hole that penetrates the base 35 in the above-described position in the axial direction. In the output shaft gear 23, a shaft portion 23b extends downward from the axial end of the external tooth portion 23a, and a female screw portion 23c is formed at a position corresponding to the lower shaft center of the shaft portion 23b. ing. The female screw portion 23 c is screwed into the bolt 35 a of the base portion 35. In this way, the shaft portion 23 b of the output shaft gear 23 is fixed to the base portion 35.

  Further, a substantially conical convex portion 23d centering on the female screw portion 23c projects downwardly at a position corresponding to the female screw portion 23c on the lower surface of the shaft portion 23b of the output shaft gear 23. On the other hand, a concave portion 35b having a shape corresponding to the convex portion 23d with the bolt 35a as a center is formed at a position corresponding to the bolt 35a on the upper surface of the base portion 35. In the state where the shaft portion 23b and the base portion 35 of the output shaft gear 23 are fixed as described above, the convex portion 23d and the concave portion 35b are fitted to each other. Further, as described above, the outer tooth portion 23a of the output shaft gear 23 is configured to mesh with the ring gear 7 (see FIG. 2). As a result, the output shaft gear 23 rotates with the carrier 22 and transmits the rotational driving force to the blade 6 of the wind power generator 1.

  The speed reduction mechanism 24 is for decelerating the carrier 22 at a predetermined ratio with respect to the rotational speed of the drive motor 16 and includes a first speed reduction mechanism and a second speed reduction mechanism.

  The first speed reduction mechanism includes a driven external gear 26 that meshes with the drive external gear 21a. The driven external gear 26 rotates at a predetermined reduction ratio with respect to the drive external gear 21 a by the rotation of the input shaft 21. The second reduction mechanism includes a crankshaft 46 and pinions 48 and 48.

  Three crankshafts 46 are provided, and these crankshafts 46 are arranged at equal intervals in the circumferential direction. Two pinions 48 are arranged side by side in the axial direction of the crankshaft 46. Both pinions 48 and 48 are disposed in a closed space formed between the base portion 35 and the end plate portion 36 inside the cylindrical portion 13.

  The crankshaft 46 is rotatably supported by a pair of upper and lower crank bearings 52 and 53. The lower crank bearing 52 is fitted into a through hole 36 a formed in the end plate portion 36. The upper crank bearing 53 is fitted in a recess 35 c formed on the lower surface of the base portion 35. In other words, the crankshaft 46 is supported by the end plate portion 36 via the lower crank bearing 52 at the lower portion and supported by the base portion 35 via the upper crank bearing 53 at the upper portion.

  The driven external gear 26 is provided at the lower end portion of each crankshaft 46 projecting downward from the lower crank bearing 52. Each of these driven external gears 26 meshes with the drive external gear 21a. The crankshaft 46 is decelerated at the gear ratio between the drive external gear 21 a and the driven external gear 26 and rotates integrally with the driven external gear 26.

  The crankshaft 46 is provided with two eccentric portions 46a and 46b arranged so as to correspond to the respective pinions 48. Each eccentric part 46a and 46b is formed in the column shape eccentric with respect to the axial center of the crankshaft 46, and both the eccentric parts 46a and 46b are set so that it may have a phase difference of 180 degree | times.

  Both the pinions 48 have the same configuration. As shown in FIG. 5, each pinion 48 is formed to be slightly smaller than the inner diameter of the cylindrical portion 13, and has external teeth 48 a that mesh with the internal tooth pins 18 of the cylindrical portion 13. The number of outer teeth 48a of the pinion 48 is slightly smaller than the number of teeth of the inner tooth pin 18, for example, by one.

  Each pinion 48 is provided with a first through hole 48b and a second through hole 48c (hole). The first through hole 48b is formed in a circular shape. The crankshaft 46 is inserted into the first through hole 48b with a roller bearing 55 interposed. The eccentric portions 46a and 46b are fitted in the first through holes 48b of the pinions 48 and 48, respectively. Thereby, both the pinions 48 and 48 are eccentrically rotated (revolved) while meshing with the internal tooth pin 18 of the cylindrical portion 13 in a state where the phases are shifted by 180 degrees due to the rotation of the eccentric portions 46a and 46b.

  The second through hole 48c is formed in a substantially triangular shape larger than the cross section of the shaft portion 37, and the shaft portion 37 is inserted into the second through hole 48c with a predetermined gap. Moreover, since the 2nd through-hole 48c is provided corresponding to the shaft part 37, three are provided in the circumferential direction at equal intervals. Then, the rotational movement is transmitted from the second through hole 48c to the shaft portion 37 along with the eccentric rotational motion of the pinions 48, 48, whereby the base portion 35, the end plate portion 36, and the shaft portion 37 are integrated. 22 rotates around the axis of the cylindrical portion 13.

  In the present embodiment, the width of the predetermined gap between the second through hole 48c (hole portion) and the shaft portion 37 which is a part of the base portion 35 (output shaft) is from the blade 6 to the ring gear 7 and the output. It is set to be larger than the amount of movement of the shaft portion 37 in the second through hole 48c when vibration is transmitted to the base portion 35 via the shaft gear 23. Thereby, also when a vibration is transmitted as mentioned above, it is suppressed that the shaft part 37 contacts the 2nd through-hole 48c.

  Next, the operation of the pitch driving device 10 according to the present embodiment will be described.

  When the drive external gear 21a is rotated by driving the drive motor 16, the driven external gear 26 is rotated by being decelerated at a predetermined reduction ratio by the first speed reduction mechanism. As the driven external gear 26 rotates, the crankshaft 46 rotates together. As a result, the eccentric portions 46a and 46b rotate, whereby both the pinions 48 make an eccentric rotational movement (revolution) while meshing with the internal tooth pin 18. Accordingly, the crankshaft 46 also revolves. At this time, the driven external gear 26 revolves around the drive external gear 21a. And the shaft part 37 revolves with the eccentric rotational movement (revolution) of both the pinions 48, and the carrier 22 whole rotates. The rotation of the carrier 22 is greatly decelerated with respect to the rotation of the crankshaft 46. As a result, the output shaft gear 23 rotates at a rotational speed significantly reduced with respect to the rotational speed of the drive motor 16. The rotation of the output shaft gear 23 rotates the ring gear 7 to change the direction of the blade 6.

  In the present embodiment, as described above, there is no spline coupling portion between the output shaft gear 23 and the base portion 35, and the tooth portion 23a and the shaft portion 23b of the output shaft gear 23 are integrally formed. Since the shaft portion 23b and the base portion 35 are fixed by screwing the bolt 35a and the female screw portion 23c, no rattling occurs between the shaft portion 23b and the base portion 35. For this reason, even when an impact or vibration is transmitted from the blade 6 to the output shaft gear 23 through the ring gear 7 due to a gust of wind, the output shaft gear 23 caused by rattling such as spline coupling and the like The base 35 is not damaged or worn. For this reason, in the pitch drive device 10 according to the present embodiment, the service life of the output shaft gear 23 and the base portion 35 can be extended.

  In the present embodiment, the bolt 35a provided on the base 35 and the female screw portion 23c provided on the shaft 23b of the output shaft gear 23 are screwed together, so that the shaft 23b and the base 35 of the output shaft gear 23 are engaged. Can be easily manufactured.

  Further, in the present embodiment, the gap between the second through hole 48c of the pinion 48 and the shaft portion 37 is such that when vibration is transmitted from the blade 6 to the base portion 35 via the ring gear 7 and the output shaft gear 23, Since the shaft portion 37 is formed to have a width larger than the amount of movement of the shaft portion 37 in the second through hole 48 c according to vibration, vibration is transmitted from the blade 6 to the base portion 35 via the ring gear 7 and the output shaft gear 23. In this case, the shaft portion 37 does not contact the second through hole 48c of the pinion 48. In other words, the above vibration can be absorbed by the gap between the second through hole 48 c and the shaft portion 37. For this reason, wear of the shaft portion 37 of the base portion 35 and vibration transmission to the speed reduction mechanism 24 can be suppressed.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is shown not by the above description of the embodiments but by the scope of claims for patent, and further includes meanings equivalent to the scope of claims for patent and all modifications within the scope.

  For example, in the above embodiment, the ring gear 7 is provided on the blade 6 and the pitch driving device 10 is provided on the hub 5. However, the present invention is not limited to this, and the ring gear 7 is provided on the hub 5 and A pitch driving device 10 may be provided.

  Moreover, although the said embodiment demonstrated the example which applied this invention to the pitch drive device 10 used for changing the direction of the braid | blade 6, this invention is not limited to this, It is used for changing the direction of the nacelle 3. The present invention may be applied to a nacelle driving device. In this case, an internal gear (ring gear) may be provided at the lower portion of the nacelle 3 and a nacelle driving device may be provided at the upper end portion of the column 2. Further, an internal gear (ring gear) may be provided at the upper end of the support column 2, and a nacelle driving device may be provided below the nacelle 3. In this case, the direction of the nacelle 3 is changed by meshing and rotating the output shaft gear (external gear) of the nacelle drive device in the same manner as in the above embodiment.

  Moreover, in the said embodiment, while forming the internal thread part 23c in the axial part 23b of the output shaft gear 23, and providing the volt | bolt 35a screwed together with the internal thread part 23c in the base 35, this invention is not restricted to this, Output A bolt may be provided on the shaft portion 23 b of the shaft gear 23, and a female screw portion to be screwed to the bolt may be formed on the base portion 35. In the above-described embodiment, the bolt 35a is used as the male screw portion. However, the present invention is not limited to this. Another configuration such as a single unit may be applied.

  Moreover, in the said embodiment, although the volt | bolt 35a and the internal thread part 23c as an external thread part were each provided in the position corresponding to the axial center of the base 35, and the position corresponding to the axial center of the axial part 23b of the output shaft gear 23, it was. The present invention is not limited to this, and the male screw portion and the female screw portion may be provided at positions other than the shaft center 23 b of the output shaft gear 23 and the shaft center of the base portion 35.

It is the figure which showed the principal part of the wind power generator to which the pitch drive device by one Embodiment of this invention was applied. It is a figure which shows the coupling | bond part of the hub and braid | blade of the wind power generator shown in FIG. 1, and the pitch drive device installed there. It is sectional drawing which shows the whole structure of the pitch drive device shown in FIG. It is the figure which looked at the pitch drive device shown in FIG. 3 from the arrow IV direction in FIG. FIG. 5 is a cross-sectional view taken along line VV of the pitch driving device shown in FIG. 3.

Explanation of symbols

3 Nacelle 5 Hub (second member)
6 Blade (first member)
7 Ring gear (internal gear)
10 Pitch drive device (wind turbine drive device)
16 Drive motor (motor)
21 Input shaft 23 Output shaft gear (external gear)
23a External tooth part (tooth part)
23b Shaft portion 23c Female thread portion 24 Reduction mechanism 35 Base portion (output shaft)
35a Bolt (Male thread)
37 Shaft 48 Pinion (Eccentric rotating gear)
48c Second through hole (hole)

Claims (3)

A first member made of a nacelle or a blade is supported so as to be relatively rotatable with respect to a second member that supports the first member,
An internal gear is provided on one of the first member and the second member, and an external gear that meshes with the internal gear is provided on a carrier that is rotated by a speed reduction mechanism .
A windmill drive device that changes the orientation of the first member relative to the second member by rotation of the carrier ,
The external gear includes a tooth portion meshing with the internal gear and a shaft portion formed integrally with the tooth portion, and the shaft portion is fixed to the carrier . One of the shaft portion of the external gear and the carrier has a male screw portion, and the other of the shaft portion of the external gear and the carrier has a female screw portion screwed into the male screw portion. Item 2. The windmill drive device according to Item 1. The speed reduction mechanism includes an eccentric rotation gear that rotates eccentrically as the input shaft rotates by driving a motor, and is coupled to the carrier .
Wherein the eccentric rotation gear, together with the hole is formed, the carrier is inserted in a state of having a gap into the hole, so that the carrier is rotated along with the eccentric rotation of the eccentric rotation gear Is composed of
Wherein the width of the gap between the hole of the eccentric rotation gear and said carrier, said carrier in said hole portion is larger than the amount of movement when vibrations from the first member to the carrier is transmitted, claims The windmill drive device according to 1 or 2.

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