JP4703578B2 - Francis turbine - Google Patents

Description

  The present invention relates to a Francis turbine capable of efficiently suppressing the generation of hydraulic power loss due to a secondary flow generated at a non-design point.

  As shown in FIG. 8, the Francis type turbine includes a casing 1 into which water flows from an upper pond (not shown), a main shaft 6 that is connected to a generator 7 at one end and is rotatably arranged, and a casing 1 The guide vane 3 that guides the water flowing into the casing 1, the stay vane 2 that is disposed in the casing 1 and upstream of the guide vane 3, and the tip of the main shaft 6 are connected to the guide vane. 3, and a runner 4 that rotates in response to water from 3. As shown in FIG. 8, a suction pipe 5 that receives water obtained by rotating the runner 4 and discharges it to a lower pond (not shown) is connected to the casing 1. As shown in FIG. 8, the runner 4 is disposed between the crown 9, the band 10, and the crown 9 and the band 10, and the runner blade inlet end 18 p provided on the water inflow side. And a plurality of runner blades 18 having runner blade outlet end portions 18q provided on the side from which water flows out.

  In the configuration as described above, first, water flows into the casing 1 from the upper pond (not shown). Next, the water that has flowed into the casing 1 reaches the guide vane 3 through the stay vane 2, and is guided to the runner 4 by the guide vane 3. The water guided to the runner 4 rotates the runner blades 18 around the main shaft 6 to drive the generator 7 and generate electricity. Finally, the water that has rotated the runner 4 is discharged to the lower pond through the suction pipe 5.

  In the flow of water as described above, the power generation amount is adjusted by adjusting the opening of the guide vane 3 and adjusting the amount of water flowing into the runner 4. For this reason, the flow of water in the runner 4 varies greatly depending on the operation state (opening degree of the guide vane 3).

  FIG. 9A schematically shows the meridional flow in the runner 4 when the amount of water flowing into the runner 4 is at the design point (the point where power generation efficiency is to be maximized). 9 (b) schematically shows the meridian flow in the runner 4 when the amount of water flowing into the runner 4 is smaller than the amount of water at the design point. FIG. 9 (c) The figure shows schematically the meridional surface flow in the runner 4 when the amount of water flowing into the interior is larger than the amount of water at the design point.

  The meridional flow in the runner 4 is generated by the water flowing into the runner 4, and is generated by the dynamic pressure K trying to push the water into the inner peripheral side and the runner 4 rotating, and the water is moved to the outer peripheral side. It is determined by the balance of the centrifugal force C to be pushed out (see FIG. 9A). For this reason, as shown in FIG. 9B, when the amount of water flowing into the runner 4 is smaller than the amount of water at the design point, the centrifugal force C is larger than the dynamic pressure K, and the water flow is on the outer peripheral side. Biased toward For this reason, as shown in FIG. 9B, a dead water region 33 where no water flows is formed on the inner peripheral side of the runner 4. On the other hand, as shown in FIG. 9C, when the amount of water flowing into the runner 4 is larger than the amount of water at the design point, the centrifugal force C becomes smaller than the dynamic pressure K, and the flow of water is reduced. It is biased toward the inner circumference. For this reason, as shown in FIG. 9C, a dead water region 33 in which no water flows is formed on the outer peripheral side of the runner 4. Such a biased water flow is called a secondary flow and is a main cause of hydraulic loss occurring in the runner 4 at non-design points.

In order to reduce the secondary flow at such a non-design point, as shown in FIG. 10, the side surface of the runner blade 18 extends from the runner blade inlet end portion 18p toward the runner blade outlet end portion 18q. A configuration in which the rectifying blade 14 having a chord length shorter than the chord length of the runner blade 18 is provided (see, for example, Patent Documents 1-3).
JP-A-57-126666 JP-A-8-296544 JP 2005-133698 A

  However, when the rectifying blade 14 is attached in the vicinity of the band 10 of the runner 4 or the length of the rectifying blade 14 is insufficient, the hydraulic efficiency is hardly improved, and only the manufacturing cost due to the attachment of the rectifying blade 14 is increased. Cases have been reported. This suggests that it is difficult to effectively suppress the secondary flow and reduce hydraulic loss unless the length of the rectifying blades 14 and the arrangement position of the rectifying blades 14 are optimized.

  The present invention has been made in consideration of such points, and an object of the present invention is to provide a Francis-type turbine capable of efficiently suppressing the generation of hydraulic loss due to the secondary flow generated at a non-design point. .

  The present invention includes a crown, a band, a runner blade inlet end provided on the side from which water flows in, and a runner blade outlet provided on the side from which water flows out. In a Francis type turbine having a plurality of runner blades having end portions and rectifying blades provided on side surfaces of the runner blades and extending from the runner blade inlet end portion toward the runner blade outlet end portion side, the runner blades The relationship between the dimension H in the height direction of the runner blade at the inlet end and the distance h in the height direction from the crown of the rectifying blade at the inlet end of the runner is 0.1 ≦ h / H ≦ 0.3. It is a Francis type water wheel characterized by becoming.

  The present invention includes a crown, a band, a runner blade inlet end provided on the side from which water flows in, and a runner blade outlet provided on the side from which water flows out. In a Francis type turbine having a plurality of runner blades having end portions, and rectifying blades provided on side surfaces of the runner blades and extending from the runner blade inlet end portion toward the runner blade outlet end portion side, The Francis type turbine is characterized in that the relationship between the chord length C of the runner blade and the chord length c of the rectifying blade is 0.7 ≦ c / C.

  According to the present invention, the relationship between the height direction dimension H of the runner blade at the runner blade inlet end and the distance h in the height direction from the crown of the flow straightening blade at the runner blade inlet end is adjusted. By efficiently adjusting the relationship between the chord length C of the runner blades and the chord length c of the rectifying blades at the mounting position, it is possible to efficiently suppress the generation of hydraulic loss due to the secondary flow generated at the non-design point. Can do.

First Embodiment Hereinafter, a first embodiment of a Francis type turbine according to the present invention will be described with reference to the drawings. Here, FIG. 1 thru | or FIG. 5 (a) (b) is a figure which shows the 1st Embodiment of this invention.

  As shown in FIG. 1, the Francis type turbine according to the present embodiment includes a casing 1 into which water flows from an upper pond (not shown), and a main shaft 6 that is rotatably connected to one end of a generator 7. And a guide vane 3 disposed in the casing 1 for guiding water flowing into the casing 1, a stay vane 2 disposed in the casing 1 on the upstream side of the guide vane 3, and a tip of the main shaft 6. The runner 4 is connected and rotated by receiving water from the guide vane 3.

  As shown in FIG. 1, the casing 1 is connected to a suction pipe 5 that receives water obtained by rotating the runner 4 and discharges it to a lower pond (not shown).

  As shown in FIGS. 1 to 3, the runner 4 is disposed between the crown 9, the band 10, the crown 9 and the band 10, and the runner blade inlet provided on the water inflow side. A plurality of runner blades 18 having end portions 18p and runner blade outlet end portions 18q provided on the side from which water flows out, and provided on the side surfaces of the runner blades 18 from the runner blade inlet end portions 18p to the runner blade outlet ends. And a straightening blade 14 extending toward the portion 18q. 2A and 2B, the rectifying blades 14 are provided between the runner blades 18 adjacent to each other.

  2A shows a streamline development view of the runner 4 in the Francis turbine according to the present embodiment, and FIG. 2B shows an inter-blade flow of the runner 4 in the Francis turbine according to the present embodiment. A road map is shown, and FIG. 3 shows a meridional section of the runner 4 in the Francis type turbine according to the present embodiment.

  Further, in FIG. 3, the relationship between the dimension H in the height direction of the runner blade 18 at the runner blade inlet end portion 18 p and the distance h in the height direction from the crown 9 of the rectifying blade 14 at the runner blade inlet end portion 18 p is 0.1 ≦ h / H ≦ 0.3.

  Next, the function and effect of the Francis turbine according to the present embodiment having such a configuration will be described.

  Initially, the effect of the Francis type turbine in this Embodiment is demonstrated along the flow of the inflowing water.

  First, water is introduced from the upper pond (not shown) into the casing 1 (inflow process 81) (see FIGS. 1 and 4).

  Next, the water that has flowed into the casing 1 reaches the guide vane 3 through the stay vane 2 and is guided to the runner 4 by this guide vane 3 (guide step 82) (see FIGS. 1 and 4). At this time, the operator can adjust the amount of electricity generated by the Francis turbine by changing the opening of the guide vane 3 to change the amount of water flowing into the runner 4.

  The water guided to the runner 4 rotates the runner blades 18 of the runner 4 around the main shaft 6 (runner rotation step 83). At this time, the generator 7 connected to the main shaft 6 is driven to generate electricity (power generation step 84) (see FIGS. 1 and 4). In this way, when water flows into the runner 4 and the runner blade 18 is rotated around the main shaft 6 (in the runner rotation step 83), a secondary flow of water is generated.

  Finally, the water which rotated the runner 4 is discharged | emitted to the lower pond (not shown) through the suction pipe 5 (discharge process 84) (refer FIG.1 and FIG.4).

  Next, as described above, a configuration for reducing the secondary flow generated when the runner blade 18 is rotated around the main shaft 6 (in the runner rotation step 83) will be described.

  Of the secondary flows generated when the runner blades 18 are rotated around the main shaft 6 (in the runner rotation step 83), the secondary flow on the outer peripheral side arranges the rectifying blades 14 on the band 10 side of the runner blades 18. Can be reduced. On the other hand, the secondary flow on the inner peripheral side can be reduced by arranging the flow straightening blade 14 on the crown 9 side of the runner blade 18. As described above, since the effect of reducing the secondary flow differs depending on the position of the rectifying blade 14 at the runner blade 18, the height direction from the crown 9 of the rectifying blade 14 at the runner blade inlet end 18 p is different. It can be seen that there is an appropriate value for h / H obtained by dividing the distance h by the dimension H in the height direction of the runner blade 18 at the runner blade inlet end 18p.

  FIG. 5A shows the relationship between the amount of water flowing into the runner 4 and hydraulic loss with respect to the Francis turbine with the rectifying blades 14 and the Francis turbine without the rectifying blades 14. Further, in FIG. 5B, with respect to representative water amount operation points (60% water amount operation point, 80% water amount operation point, 100% water amount operation point), the runner blade inlet end portion 18p from the crown 9 of the rectifying blade 14 is shown. The relationship between h / H obtained by dividing the distance h in the height direction by the dimension H in the height direction of the runner blade 18 at the runner blade inlet end 18p and the hydraulic loss reduction amount ΔL is shown.

  The hydraulic loss reduction amount ΔL is defined as L0−L1 obtained by subtracting the hydraulic loss L1 in the Francis turbine having the rectifying blades 14 from the hydraulic loss L0 in the Francis turbine having no rectifying blades 14. That is, ΔL = L0−L1.

  From FIG. 5 (b), the distance h in the height direction from the crown 9 of the straightening blade 14 at the runner blade inlet end 18p is divided by the dimension H in the height direction of the runner blade 18 at the runner blade inlet end 18p. When h / H satisfies the relationship of 0.1 ≦ h / H ≦ 0.3, it can be seen that the hydraulic loss reduction amount ΔL is large. Therefore, as in this embodiment, the distance h in the height direction from the crown 9 of the rectifying blade 14 at the runner blade inlet end 18p is the dimension in the height direction of the runner blade 18 at the runner blade inlet end 18p. By providing the flow straightening blade 14 on the side surface of the runner blade 18 such that h / H divided by H is 0.1 ≦ h / H ≦ 0.3, the hydraulic power by the secondary flow generated at the non-design point Loss generation can be efficiently suppressed.

  From FIG. 5 (b), the numerical value is limited (0.1 ≦ h / H ≦ 0.3) and the numerical value is not limited (h / H <0.1 and h / H> 0.3). It is clear that there are significant differences in quantity.

Second Embodiment Next, a second embodiment of the present invention will be described with reference to FIGS. 6 and 7A and 7B. In the second embodiment shown in FIGS. 6 and 7A and 7B, the dimension H in the height direction of the runner blade 18 at the runner blade inlet end 18p and the rectifying blade 14 at the runner blade inlet end 18p. Instead of providing the rectifying blade 14 on the side surface of the runner blade 18 such that the relationship with the distance h in the height direction from the crown 9 is 0.1 ≦ h / H ≦ 0.3, The rectifying blade 14 is provided on the side surface of the runner blade 18 such that the chord length C of the runner blade 18 at the mounting position and the chord length c of the rectifying blade 14 is 0.7 ≦ c / C. The others are substantially the same as those of the first embodiment shown in FIGS. 1 to 5A and 5B.

  In the second embodiment shown in FIGS. 6 and 7A and 7B, the same reference numerals are given to the same portions as those in the first embodiment shown in FIGS. 1 to 5A and 5B. Detailed description will be omitted. FIG. 6 shows a meridional section of the Francis type turbine according to the present embodiment.

  In general, when the chord length c of the rectifying blade 14 is smaller than the chord length C of the runner blade 18, the rectifying blade 14 is unbalanced with respect to the runner blade 18 and is generated by such an unbalance. The hydraulic power loss becomes larger than the hydraulic power loss reduced by the rectifying action by the rectifying blade 14. For this reason, the deviation of the meridional flow in the runner 4 cannot be sufficiently reduced, and a secondary flow of water is generated. Therefore, the chord length c of the rectifying blade 14 needs to be somewhat larger than the chord length C of the runner blade 18.

  FIG. 7A shows the relationship between the amount of water flowing into the runner 4 and hydraulic loss for the Francis turbine with the rectifying blades 14 and the Francis turbine without the rectifying blades 14. FIG. 7B shows the chord length c of the rectifying blade 14 with respect to the representative water amount operating point (60% water amount operating point, 80% water amount operating point, 100% water amount operating point). The relationship between c / C divided by the chord length C of the runner blade 18 at the position and the hydraulic loss reduction amount ΔL is shown.

  7 (b), c / C obtained by dividing the chord length c of the rectifying blade 14 by the chord length C of the runner blade 18 at the mounting position of the rectifying blade 14 has a relationship of 0.7 ≦ c / C. When satisfy | filling, it turns out that hydraulic loss reduction amount (DELTA) L is large. Therefore, as in the present embodiment, c / C obtained by dividing the chord length c of the rectifying blade 14 by the chord length C of the runner blade 18 at the mounting position of the rectifying blade 14 is 0.7 ≦ c / By providing the rectifying blades 14 having chord lengths such as C on the side surfaces of the runner blades 18, it is possible to efficiently suppress the generation of hydraulic loss due to the secondary flow generated at the non-design point.

  From FIG. 7 (b), it is clear that there is a significant difference between the numerical limitation (0.7 ≦ c / C) and the numerical limitation (c / C <0.7). is there.

  In the above, the first embodiment and the second embodiment have been described separately. However, the aspect shown in the first embodiment and the aspect shown in the second embodiment are described above. It is also possible to use a Francis type turbine in combination with

  That is, the relationship between the dimension H in the height direction of the runner blade 18 at the runner blade inlet end 18p and the distance h in the height direction from the crown 9 of the rectifying blade 14 at the runner blade inlet end 18p is 0.1. ≦ h / H ≦ 0.3, and the relationship between the chord length C of the runner blade 18 and the chord length c of the rectifying blade 14 at the mounting position of the rectifying blade 14 is 0.7 ≦ c / C. Such a rectifying blade 14 may be provided on the side surface of the runner blade 18.

  According to such a Francis type turbine, the generation of hydraulic power loss due to the secondary flow generated at the non-design point can be more efficiently suppressed.

1 is a longitudinal sectional view showing a first embodiment of a Francis type turbine according to the present invention. The streamline expanded view and flow path diagram between wings which show the runner in the Francis type turbine by the 1st embodiment of the present invention. 1 is a meridional section view of a runner in a Francis type turbine according to a first embodiment of the present invention. The flowchart explaining the effect of the Francis type water turbine by this invention. The graph which shows the relationship between the water quantity and hydraulic loss in 1st Embodiment of the Francis type turbine by this invention, and h / H and hydraulic loss fall amount (DELTA) L. The meridian plane sectional view of the runner in the Francis type turbine by the 2nd embodiment of the present invention. The graph which shows the relationship between the water quantity and hydraulic loss, and h / H and hydraulic loss fall amount (DELTA) L in 2nd Embodiment of the Francis type turbine by this invention. The longitudinal cross-sectional view which shows the conventional Francis type water turbine. The schematic diagram which showed the difference in the meridional surface flow by the difference in the amount of water which flows in in a runner in the conventional Francis type water turbine. The longitudinal cross-sectional view which shows the conventional Francis type | mold water turbine provided with the baffle blade.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Casing 2 Stay vane 3 Guide vane 4 Runner 6 Main shaft 7 Generator 9 Crown 10 Band 14 Rectification blade 18 Runner blade 18p Runner blade inlet end 18q Runner blade outlet end H In the runner blade inlet end Dimension h Distance in the height direction from the crown of the rectifying blade at the runner blade inlet end C Length of the chord of the runner blade at the position where the rectifying blade is attached c Length of chord K of the rectifying blade K Dynamic pressure due to water flowing into the runner C Centrifugal force caused by rotating runner

Claims (3)

With the crown,
With the band,
A plurality of runner blades disposed between the crown and the band and having runner blade inlet end portions provided on a water inflow side and runner blade outlet end portions provided on a water outflow side; ,
In the Francis type turbine provided with the rectifying blade provided on the side surface of the runner blade and extending from the runner blade inlet end toward the runner blade outlet end,
The relationship between the dimension H in the height direction of the runner blade at the runner blade inlet end and the distance h in the height direction from the crown of the rectifying blade at the runner blade inlet end is:
0.1 ≦ h / H ≦ 0.3
Francis type water wheel characterized by becoming. With the crown,
With the band,
A plurality of runner blades disposed between the crown and the band and having runner blade inlet end portions provided on a water inflow side and runner blade outlet end portions provided on a water outflow side; ,
In the Francis type turbine provided with the rectifying blade provided on the side surface of the runner blade and extending from the runner blade inlet end toward the runner blade outlet end,
The relationship between the chord length C of the runner blade and the chord length c of the rectifying blade at the mounting position of the rectifying blade is
0.7 ≦ c / C
Francis type water wheel characterized by becoming. The relationship between the dimension H in the height direction of the runner blade at the runner blade inlet end and the distance h in the height direction from the crown of the rectifying blade at the runner blade inlet end is:
0.1 ≦ h / H ≦ 0.3
The Francis type turbine according to claim 2, wherein

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