JP4770681B2 - Vertical shaft pump - Google Patents

Description

  The present invention relates to a vertical shaft pump installed in a drainage station or the like.

  A vertical shaft pump installed in a drainage station or the like is provided with an impeller, a casing containing the impeller, a bend pipe connected to the downstream side of the casing, and a casing and the bend pipe rotatably provided with a bearing device. A rotating shaft having an impeller attached to the lower end, a protective tube covering the rotating shaft, and a prime mover connected to the upper end of the rotating shaft protruding above the bend tube. In this vertical shaft pump, it is difficult to ensure a sufficient radius of curvature of the bend pipe in order to prevent an increase in size. In such a case, separation occurs in the water flow flowing along the bent inner wall surface of the bend pipe, and the water channel loss (mixing loss) increases, so that the pump performance is deteriorated. Therefore, a structure in which a current plate is provided on the inner side of the center line of the bend pipe has been proposed (for example, see Patent Document 1). Thereby, separation in the water flow flowing along the bent inner wall surface of the bend pipe is suppressed, and the water channel loss is reduced.

JP 2004-27999 A

However, the above prior art has room for improvement as follows.
That is, it may be difficult to ensure a sufficient radius of curvature of the rectifying plate. In such a case, separation occurs in the water flow that flows along the outer peripheral surface of the rectifying plate, and water channel loss (mixing loss) increases. . Therefore, there is room for improvement in terms of suppressing separation in the water flow that flows along the outer peripheral surface of the current plate and reducing water channel loss.

  This invention is made | formed based on said matter, The objective is to provide the vertical shaft pump which can aim at reduction of a channel loss.

  (1) To achieve the above object, the present invention provides an impeller, a casing containing the impeller, a bend pipe connected to the downstream side of the casing, and rotatable in the casing and the bend pipe. A vertical shaft pump provided with a rotary shaft connected to the impeller and a protective pipe covering the circumference of the rotary shaft, wherein the bend pipe is a first rectification provided inside a center line of the bend pipe And a second rectifying plate provided on the downstream side and the inside of the first rectifying plate so as to form a gap between the first rectifying plate and the first rectifying plate. The downstream end of the rectifying plate has a shape that generates a width direction component of the first rectifying plate in the flow passing through the gap between the first rectifying plate and the second rectifying plate.

  In the present invention, on the downstream side and the inside of the first rectifying plate, a gap is formed between the first rectifying plate provided on the inner side of the center line of the bend pipe and the first rectifying plate. And a second rectifying plate provided in a shifted manner. Thereby, the fluid that flows along the inner peripheral surface of the first rectifying plate flows into the outer region of the second rectifying plate through the gap between the first rectifying plate and the second rectifying plate, 2 flows along the outer peripheral surface of the current plate. That is, a high energy flow inside the first rectifying plate can be applied to the outer region of the second rectifying plate. This suppresses separation in the water flow flowing along the outer peripheral surface of the second rectifying plate, and further has an effect of suppressing separation in the water flow flowing along the outer peripheral surface of the upstream first rectifying plate. Loss can be reduced.

  Further, in a curved flow path such as a bend pipe, a secondary flow is generated in the cross section of the flow path due to centrifugal force acting on the fluid. Then, due to the influence of the flow passing through the gap between the first rectifying plate and the second rectifying plate and the flow in the downstream area of the protective tube, a low speed region is formed in the outer region of the first and second rectifying plates. If this low speed region is large, water channel loss (mixing loss) will increase. Therefore, in the present invention, the downstream side end portion of the first rectifying plate is formed in, for example, an arc shape or a shape having a hypotenuse inclined in the width direction of the first rectifying plate, whereby the first rectifying plate is formed. A component in the width direction of the first rectifying plate is generated in the flow passing through the gap between the first rectifying plate and the second rectifying plate. The flow in the width direction component promotes the secondary flow in the outer region of the first and second rectifying plates, and the low-speed region can be reduced by the secondary flow. Therefore, the water channel loss can be further reduced.

  (2) In the above (1), preferably, the downstream step portion of the first rectifying plate is formed in an arc shape.

  (3) In the above (1), preferably, the downstream end of the first rectifying plate is formed in a shape having a hypotenuse inclined in the width direction of the first rectifying plate.

  According to the present invention, the fluid flowing along the inner peripheral surface of the first rectifying plate flows into the outer region of the second rectifying plate through the gap between the first rectifying plate and the second rectifying plate. And flows along the outer peripheral surface of the second current plate. Thereby, peeling in the water flow which flows along the outer peripheral surface of a 2nd baffle plate can be suppressed, and a water channel loss can be reduced. Further, by generating a width direction component of the first rectifying plate in the flow passing through the gap between the first rectifying plate and the second rectifying plate, in the outer region of the first and second rectifying plates The secondary flow is promoted, and the low speed region can be narrowed by the secondary flow. Therefore, the water channel loss can be further reduced.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a cross-sectional view showing the overall structure of an embodiment of a vertical pump according to the present invention, FIG. 2 is a cross-sectional view taken along section II-II in FIG. 1, and FIG. FIG. FIG. 4 is a diagram showing a flow passing through a gap between a first rectifying plate and a second rectifying plate, which will be described later (however, for convenience, the second rectifying plate is not shown). FIG. 5 is a diagram illustrating a secondary flow of the cross section of the flow path at the cross section VV in FIG. 1.

  In FIG. 1 to FIG. 5, the vertical shaft pump 1 is, for example, an axial flow pump installed in a drainage station, and includes an impeller 2, a cylindrical casing 3 containing the impeller 2, and the casing 3. A suction bell mouth 4 connected to the upstream side (lower side in FIG. 1), a bend pipe 5 connected to the downstream side (upper side in FIG. 1) of the casing 3, and a downstream side of the bend pipe 5 (in FIG. 1) A drainage pipe 6 connected to the right side), a rotary shaft (shaft) 8 which is rotatably provided in the casing 3 and the bend pipe 5 via a bearing 7 and has an impeller 2 attached to the lower end thereof; And a prime mover (not shown) connected to the upper end portion of the rotary shaft 7 protruding upward. When the impeller 2 rotates through the rotary shaft 8 by driving the prime mover, the pressure of the water flowing into the casing 3 through the suction bell mouth 4 from the water suction passage 9 is increased and released through the bend pipe 5 and the drain pipe 6. It is designed to be discharged into a water channel (not shown).

  A suction cone 10 is provided at the center of the suction bell mouth 4, and a plurality of guide vanes 11 are provided between the suction cone 10 and the suction bell mouth 4. A bearing sleeve 12 that houses the bearing 7 is provided on the downstream side of the impeller 2 at the center of the casing 3, and a plurality of guide vanes 13 are provided between the bearing sleeve 12 and the casing 3. ing. A protective tube 14 connected to the bearing sleeve 12 is provided in the bend tube 5, and the bearing sleeve 12 and the protective tube 14 cover the periphery of the rotating shaft 8.

  The bend pipe 5 which is a main part of the present embodiment has, for example, a circular channel cross section and a structure bent at 90 degrees. In the bend pipe 5, a first rectifying plate 15 provided on the inner side of the center line O of the bend pipe 5 and a second rectifying plate provided on the downstream side and inside of the first rectifying plate 15 are provided. A rectifying plate 16 is provided.

  The first rectifying plate 15 is formed so that a semicircular plate having a circular end at the downstream end is curved along the bending direction of the bend tube 5, and the radius of curvature R 1 is the center line of the bend tube 5. The curvature radius of O is smaller than R0. The first rectifying plate 15 has an upstream end spaced from the protective tube 14 and two corners thereof welded to the tube wall of the bend tube 5, and the center of the downstream end is protected via the support rod 17. 14. By adopting such a support structure for the first rectifying plate 15, vibration of the first rectifying plate 15 due to the influence of the flow in the bend pipe 5 is suppressed. As shown in FIG. 3, the cross-sectional shape of the support rod 17 is formed so that, for example, the upstream side has a relatively large arc shape and the downstream side has a relatively small arc shape so as to reduce the fluid resistance.

  The second rectifying plate 16 is curved along the bending direction of the bend pipe 5 with a plate cut out in an arc shape so that the upstream end corresponds to the downstream end of the first rectifying plate 15. The radius of curvature R2 is smaller than the radius of curvature R1 of the first current plate 15. The upstream end portion of the second rectifying plate 16 is, for example, separated from the downstream end portion of the first rectifying plate 15 in the bending direction of the bend pipe 5, and the first rectifying plate 15 and the second rectifying plate 15 are separated from each other. A gap 18 is formed between the current plate 16 and the current plate 16.

  In the present embodiment configured as described above, the fluid flowing along the inner peripheral surface of the first rectifying plate 15 passes through the gap 18 between the first rectifying plate 15 and the second rectifying plate 16. It flows into the outer region of the second rectifying plate 16 and flows along the outer peripheral surface of the second rectifying plate 16 (shown by an arrow A in FIG. 1). That is, a high energy flow inside the first rectifying plate 15 can be applied to the outer region of the second rectifying plate 16. This suppresses separation in the water flow that flows along the outer peripheral surface of the second rectifying plate 16, and further has an effect of suppressing separation in the water flow that flows along the outer peripheral surface of the first rectifying plate 15 on the upstream side. Can reduce water channel loss.

  Further, in the present embodiment, by forming the downstream end portion of the first rectifying plate 15 in an arc shape, the first rectifying plate 15 and the second rectifying plate 16 are connected as shown in FIG. A width direction component B of the first rectifying plate 15 is generated in the flow passing through the gap 18 (in other words, the degree of freedom of flow is increased). The effect will be described below using a comparative example.

  FIG. 6 is a diagram illustrating the structures of the first and second rectifying plates according to the comparative example, and corresponds to FIG. 2 described above. FIG. 7 is a diagram showing a flow passing through the gap between the first rectifying plate and the second rectifying plate in the comparative example (however, for convenience, the second rectifying plate is not shown), This corresponds to FIG. 4 described above. Moreover, FIG. 8 is a figure showing the secondary flow of the flow-path cross section in a comparative example, and is equivalent to the above-mentioned FIG.

  In the comparative examples shown in FIG. 6 to FIG. 8, similarly to the above-described embodiment, the bend pipe 5 includes the first rectifying plate 19 provided on the inner side of the center line O of the bend pipe 5 and the first rectifying plate 19. A second rectifying plate 21 is provided so as to be shifted downstream and inward from the first rectifying plate 19 so as to form a gap 20 with the rectifying plate 19. However, unlike the above-described embodiment, the downstream end of the first rectifying plate 19 and the upstream end of the second rectifying plate 21 are formed in a straight line. Therefore, the flow passing through the gap 20 between the first rectifying plate 19 and the second rectifying plate 21 is substantially only in the bending direction of the bend pipe 5 (right direction in FIG. 7). Then, due to the influence of the flow passing through the gap 20 between the first rectifying plate 19 and the second rectifying plate 21 and the flow C in the downstream area of the protective tube 14, the outer region of the first rectifying plate 19 Has a low speed region D1, which is relatively large (see FIG. 8).

  On the other hand, in the present embodiment, the downstream end portion of the first rectifying plate 15 is formed in an arc shape so as to pass through the gap 18 between the first rectifying plate 15 and the second rectifying plate 16. A width direction component (secondary flow component) of the first rectifying plate 15 is generated in the flow. The secondary flow in the outer region of the first rectifying plate 15 is promoted by the flow in the width direction component, the secondary flow E flowing in the center of the flow path cross section is generated, and the low speed region D2 is reduced by the secondary flow (See FIG. 5). Therefore, in this embodiment, water channel loss can be further reduced.

  In the above embodiment, the case where the downstream end portion of the first rectifying plate 15 is formed in an arc shape has been described as an example, but the present invention is not limited thereto. That is, for example, the first current plate 15 may be formed in a shape having a hypotenuse inclined in the width direction. Specifically, as shown in FIG. 10, the downstream end of the first rectifying plate 15A is formed in a triangular shape, and the second upstream end is cut out in a triangular shape correspondingly. You may form in. Also in such a modification, the same effect as the above-described embodiment can be obtained.

  In the above-described embodiment, the upstream end of the second rectifying plate 16 is formed in a shape corresponding to the downstream end of the first rectifying plate 15 and is downstream of the first rectifying plate 15. Although the case where it spaced apart in the bending direction of the bend pipe | tube 5 from the side edge part was demonstrated as an example, it is not restricted to this. That is, for example, as shown in FIG. 11, the downstream end portion of the first rectifying plate 15A is formed in a triangular shape, and the upstream end portion of the second rectifying plate 16B is formed in a linear shape. The downstream end of the rectifying plate 15A and the upstream end of the second rectifying plate 16B may be disposed so as to overlap in the bending direction of the bend pipe 5. Although not shown, for example, the upstream end of the second rectifying plate is formed in a shape corresponding to the downstream end of the first rectifying plate, and overlaps with the downstream end of the first rectifying plate. You may arrange | position. Also in these modified examples, the same effect as the one embodiment can be obtained.

  In the above embodiment, the first rectifying plate 15 and the second rectifying plate 16 have been described by way of example as being bent along the bending direction of the bend pipe 5, but the present invention is not limited thereto. I can't. In other words, for example, the downstream end portion of the second rectifying plate 16 may be curved so as to be shifted to the inside of the bend pipe 5, and the radius of curvature thereof may be increased. In such a case, the same effect as described above can be obtained.

  In the above description, the bend pipe 5 having a circular channel cross section has been described as an example. However, the present invention is not limited to this. For example, a bend pipe having a rectangular channel cross section or a channel cross section having a rectangular shape from a circular shape. You may apply to the flat bend pipe etc. which change to. Moreover, although the axial flow pump has been described as an example of application of the present invention, the present invention is not limited to this, and it goes without saying that the present invention may be applied to, for example, a mixed flow pump.

It is a longitudinal section showing the whole structure of one embodiment of the vertical shaft pump of the present invention. It is sectional drawing by the cross section II-II in FIG. 1, and represents the structure of the 1st and 2nd baffle plate. It is sectional drawing by the cross section III-III in FIG. 1, and represents the cross-sectional shape of the support bar which supports the 1st baffle plate. It is a figure showing the flow which passes through the clearance gap between the 1st rectifier plate and the 2nd rectifier plate in one Embodiment of the vertical shaft pump of this invention. It is a figure showing the secondary flow of the flow-path cross section in the cross section VV in FIG. It is a figure showing the structure of the 1st and 2nd baffle plate by a comparative example. It is a figure showing the flow which passes through the clearance gap between the 1st rectifying plate and the 2nd rectifying plate in a comparative example. It is a figure showing the secondary flow of the flow-path cross section in a comparative example. It is a figure showing the structure of the modification of the 1st and 2nd baffle plate which comprises the vertical shaft pump of this invention. It is a figure showing the structure of the other modification of the 1st and 2nd baffle plate which comprises the vertical shaft pump of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Vertical shaft pump 2 Impeller 3 Casing 5 Bend pipe 8 Rotating shaft 14 Protection pipe | tube 15, 15A 1st rectifying plate 16, 16A, 16B 2nd rectifying plates 18, 18A, 18B Crevice

Claims (3)

An impeller, a casing containing the impeller, a bend pipe connected to the downstream side of the casing, a rotating shaft provided rotatably in the casing and the bend pipe, and having the impeller attached to a lower end portion thereof In a vertical shaft pump provided with a protective tube covering the periphery of the rotating shaft,
The bend pipe is formed on the downstream side of the first rectifying plate and so as to form a gap between the first rectifying plate provided inside the center line of the bend pipe and the first rectifying plate. A second rectifying plate provided to be shifted inward,
The downstream end of the first rectifying plate has a shape that generates a width direction component of the first rectifying plate in the flow passing through the gap between the first rectifying plate and the second rectifying plate. Vertical shaft pump characterized by that.   2. The vertical shaft pump according to claim 1, wherein the downstream step portion of the first rectifying plate is formed in an arc shape.   2. The vertical shaft pump according to claim 1, wherein the downstream end portion of the first rectifying plate is formed in a shape having a hypotenuse inclined in the width direction of the first rectifying plate.

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