JP7080784B2 - Vertical pump - Google Patents

Description

The present invention relates to a vertical shaft pump for the purpose of water supply and liquid supply.

As a background technique in this technical field, there is Japanese Patent Application Laid-Open No. 2017-125451 (Patent Document 1). In this publication, in order to effectively suppress the resonance phenomenon that occurs during operation in the floor portion of the vertical shaft pump including the rotary drive source, the impeller installed below the foundation floor and the impeller installed above the foundation floor It is formed by two members including a rotary drive source, a main shaft connecting the impeller and the rotary drive source to each other, a support structure installed on the foundation floor to support the rotary drive source, and a support structure in at least one of them. A vertical shaft pump is described that comprises a fastening position adjusting means that allows the fastening position at the fastening portion to be adjusted in the radial direction around the spindle (see summary).

JP-A-2017-125451

Patent Document 1 describes a vertical shaft pump that suppresses a resonance phenomenon that occurs during operation in a floor portion of a vertical shaft pump including a rotary drive source. However, Patent Document 1 does not describe suppressing the vibration of the discharge casing for circulating the fluid, which is installed in the vertical shaft pump.

Therefore, the present invention provides a vertical shaft pump that suppresses vibration of a discharge casing for circulating a fluid, which is installed in the vertical shaft pump.

In order to solve the above problems, the vertical shaft pump of the present invention includes a pump having an impeller and a pump casing covering the impeller, a pump casing connected to the pump casing via a fastening portion, and a suction port for sucking fluid. The pump pipe is connected to the pump casing via the fastening part to flow the fluid, and the pump pipe is connected to the pump pipe via the fastening part to flow the fluid to the discharge port for discharging the fluid. Has a curved portion for changing the flow direction of the fluid, a support portion for suspending from a set portion formed in a pump well, a discharge flange formed in a discharge port, and a discharge casing having a discharge casing. It has an avoidance resonance rib formed between the discharge flange and the support portion so as to connect the vertical pipe and the horizontal pipe of the discharge casing inside the curved portion. Is characterized in that one is formed at the center of the left-right direction, which is the lower side of the curved portion and is bilateral direction with respect to the discharge direction of the fluid, and a pair is formed symmetrically thereof.

According to the present invention, it is possible to provide a vertical shaft pump that suppresses vibration of a discharge casing for circulating a fluid, which is installed in the vertical shaft pump.

Issues, configurations and effects other than those described above will be clarified by the explanation of the following examples.

It is sectional drawing explaining the vertical shaft pump of this Example. It is a side view which expands and explains the discharge casing of this Example. It is a front view which expands and explains the discharge casing of this Example.

Hereinafter, examples of the present invention will be described with reference to the drawings. The same components may be designated by the same reference numerals, and the description may be omitted if the description is duplicated.

FIG. 1 is a cross-sectional view illustrating the vertical shaft pump of this embodiment.

The vertical shaft pump 100 described in this embodiment includes an impeller 1, a pump casing 2, a fastening portion (flange) 3, a pump pipe 4, a rotary shaft (shaft) 5, a suction port 6, a discharge port 7, and a coupling portion 9. It has a seal portion 10, a discharge casing 11, a bearing portion 12, an intermediate coupling portion 13, a guide blade 14, a support portion 15, a reinforcing rib 16, a discharge flange 17, and an avoidance resonance rib 20.

The vertical shaft pump 100 described in this embodiment has a single impeller 1 and a single pump casing 2 that covers the impeller 1, but a plurality of impellers 1 and these plurality of impellers 1 It may have a plurality of pump casings 2 covering the above.

The vertical shaft pump 100 described in this embodiment is suspended from a set portion (opening) 8 formed in a pump well via a support portion 15. The reinforcing rib 16 reinforces the support portion 15.

The impeller 1, the guide vane 14, and the pump casing 2, which are also called impellers, form the pump 30. The impeller 1 is rotationally driven via a rotary shaft 5 by rotationally driving a motor (not shown) connected via the coupling portion 9. When the impeller 1 is rotationally driven, the fluid sucked from the suction port 6 also called a bell mouth is boosted, rectified by the guide blade 14, and circulates through the pump pipe 4 and the discharge casing 11 also called a column pipe to discharge. Discharge from outlet 7.

The rotating shaft 5 is formed with intermediate coupling portions 13 at several locations (two locations in this embodiment). Further, the rotating shaft 5 is rotatably supported by the pump pipe 4 via the bearing portion 12 at several places (two places in this embodiment). Further, a seal portion 10 is formed at a portion where the rotating shaft 5 communicates with the discharge casing 11.

The suction port 6 and the pump casing 2 are connected, the pump casing 2 and the pump pipe 4, and the pump pipe 4 and the discharge casing 11 are connected by a fastening portion 3 having a flange formed therein.

That is, the vertical shaft pump 100 described in this embodiment is for connecting the pump 30 having the impeller 1 and the pump casing 2 covering the impeller 1 via the pump casing 2 and the fastening portion 3 to suck the fluid. The suction port 6 is connected to the pump casing 2 via the fastening portion 3, and the pump pipe 4 for flowing the fluid is connected to the pump pipe 4 and the pump pipe 4 is connected to the discharging port 7 via the fastening portion 3 to discharge the fluid. , A discharge casing 11 for circulating a fluid.

Further, the pump pipes 4 are connected by several pipes (two in this embodiment), and these several pump pipes 4 are connected by a fastening portion 3 having a flange formed therein. These several pump pipes 4 do not necessarily have the same length.

In the vertical shaft pump 100 described in this embodiment, the avoidance resonance rib 20 is formed on the lower side of the curved portion of the discharge casing 11 in order to suppress the vibration of the discharge casing 11.

The discharge casing 11 has a structure that changes the flow direction of the flowing fluid from the vertical direction to the horizontal direction. In this embodiment, the discharge casing 11 is a curved portion that bends from the vertical direction to the lateral direction in this way, and the avoidance resonance rib 20 is formed on the lower side (inside) of the curved portion.

That is, the avoidance resonance rib 20 is formed so as to connect the vertical pipe and the horizontal pipe constituting the discharge casing 11 having a curved portion from the vertical direction to the horizontal direction.

Further, the avoidance resonance rib 20 is formed between the discharge flange 17 formed in the discharge port 7 of the discharge casing 11 and the support portion 15. That is, the avoidance resonance rib 20 is formed on the outside of the pipe constituting the discharge casing 11.

In this embodiment, by forming such an avoidance resonance rib 20 in the discharge casing 11, it is possible to prevent the natural frequency of the discharge casing 11 from matching with a specific natural frequency, and to prevent the discharge casing 11 from matching with a specific natural frequency. Suppress vibration (resonance).

FIG. 2 is an enlarged side view illustrating the discharge casing of this embodiment. Further, FIG. 3 is an enlarged front view illustrating the discharge casing of the present embodiment.

In the vertical shaft pump 100 described in this embodiment, an impeller 1 and a motor (not shown) are connected via a rotary shaft 5 and are rotationally driven together. When the impeller 1 and the motor (not shown) are rotationally driven, the discharge casing 11 receives vibration generated by the rotational drive of the impeller 1 and the motor (not shown), and receives vibration in the front-rear direction (see FIG. 2). And, it vibrates in the left-right direction (see FIG. 3) (has a vibration mode).

In particular, when the natural frequency of the discharge casing 11 is in the resonance region of the natural frequency generated by the rotational drive of the impeller 1 and the rotating body composed of the impeller 1 and the motor (not shown) and the rotating shaft (shaft) 5. Becomes a large vibration.

Generally, in order to increase the natural frequency of a structure, it is known to install a single or a plurality of ribs or to increase the plate thickness of the base material. However, installing one or more ribs or increasing the thickness of the base metal inevitably increases the weight of the structural portion.

Therefore, in this embodiment, the natural frequency of the discharge casing 11 that does not form the avoidance resonance rib 20 is the rotation of the impeller 1 and the rotating body composed of the motor (not shown) and the rotating shaft (shaft) 5. When it is in the resonance region of the natural frequency generated by the drive, by forming the avoidance resonance rib 20 under the curved portion of the discharge casing 11, the entire weight of the discharge casing 11 is not significantly increased, and the discharge casing 11 is not charged. The natural frequency of the casing 11 is changed (higher). Then, the vibration (resonance) of the discharge casing 11 is suppressed.

Then, in detail, it was found that the avoidance resonance rib 20 is preferably formed between the discharge flange 17 formed in the discharge port 7 of the discharge casing 11 and the support portion 15 (FIGS. 2 and 3). reference).

Further, as shown in FIGS. 2 and 3, the avoidance resonance rib 20 is a curved portion formed on the lower side of the curved portion of the discharge casing 11 and the discharge casing 11 bends from the vertical direction to the horizontal direction. It is formed on the lower side (inside) of the curved portion, and is formed so as to connect the vertical pipe and the horizontal pipe constituting the discharge casing 11 having the curved portion that bends from the vertical direction to the horizontal direction.

Further, as shown in FIG. 3, in the avoidance resonance rib 20, at least a pair of avoidance resonance ribs 20b are formed symmetrically in the left-right direction. As a result of the analysis, by forming at least a pair of avoiding resonance ribs 20b symmetrically in the left-right direction in this way, the total weight of the discharge casing 11 is not significantly increased, and the discharge casing 11 is formed in the front-rear direction and the left-right direction. Vibration (resonance) can be suppressed. Here, in FIG. 3, the left-right direction is the direction on both sides of the discharge casing 11, and is the direction on both sides with respect to the discharge direction of the fluid (the direction perpendicular to the paper surface (plane) in FIG. 3).

In the avoidance resonance rib 20 in this embodiment, one avoidance resonance rib 20a is formed at the center of the lower side of the curved portion of the discharge casing 11 in the left-right direction, and a pair of avoidance resonance ribs 20b are formed on the left and right sides thereof. Has been done. That is, the avoidance resonance ribs 20 (three) are from a pair of avoidance resonance ribs 20b (two) symmetrically with the avoidance resonance rib 20a (one) at the center and the avoidance resonance rib 20a formed at the center thereof. It is composed.

As a result, the natural frequency of the discharge casing 11 that does not form the anti-resonance rib 20 is generated by the rotational drive of the impeller 1 and the rotating body composed of the motor (not shown) and the rotating shaft (shaft) 5. When it is in the resonance region of the natural frequency, it is possible to suppress the vibration (resonance) in the front-rear direction and the left-right direction of the discharge casing 11 and to strengthen the strength of the discharge casing 11.

Since the discharge casing 11 allows the fluid to flow through the curved portion that bends from the vertical direction to the horizontal direction, an upward stress is generated especially in the horizontal piping. Therefore, by forming one avoidance resonance rib 20a at the center of the lower side of the curved portion of the discharge casing 11 in the left-right direction, it is possible to cope with the generation of such stress and enhance the strength of the discharge casing 11.

The avoidance resonance rib 20 is preferably formed of the same material as the discharge flange 17 and the support portion 15, and stainless steel or carbon steel is used. Further, the avoidance resonance rib 20 is formed by welding or the like on the discharge flange 17 and the support portion 15.

Further, in this embodiment, the avoidance resonance rib 20 is formed at a right angle to the support portion 15. As a result, the natural frequency of the discharge casing 11 that does not form the anti-resonance rib 20 is generated by the rotational drive of the impeller 1 and the rotating body composed of the motor (not shown) and the rotating shaft (shaft) 5. When it is in the resonance region of the natural frequency, it is possible to suppress the vibration (resonance) in the front-rear direction and the left-right direction of the discharge casing 11 and to strengthen the strength of the discharge casing 11. The avoidance resonance rib 20 may be formed so as to be inclined with respect to the support portion 15.

As described above, in the vertical shaft pump 100 described in this embodiment, the avoidance resonance rib 20 that suppresses the resonance is formed on the lower side (lower side of the discharge flange 17) of the curved portion of the discharge casing 11 (see FIG. 3). ), The natural frequency of the discharge casing 11 is changed (higher), and the vibration of the discharge casing 11 is suppressed. As a result, the vertical shaft pump 100 can be operated stably.

That is, in this embodiment, the natural frequency of the discharge casing 11 that does not form the avoidance resonance rib 20 is the rotation of the impeller 1 and the rotating body composed of the motor (not shown) and the rotating shaft (shaft) 5. When it is in the resonance region of the natural frequency generated by driving, the natural frequency is changed (high) by forming the avoidance resonance rib 20 in the discharge casing 11, and the vibration (resonance) of the discharge casing 11 is suppressed. .. As described above, according to the present embodiment, the vibration (resonance) of the discharge casing 11 can be effectively suppressed.

Then, according to this embodiment, by efficiently forming the avoidance resonance rib 20 in the vicinity of the discharge casing 11 (by forming the avoidance resonance rib 20 at an appropriate position to the minimum necessary), the discharge casing is used. The natural frequency of 11 can be changed (increased), the strength can be strengthened, and the cost can be reduced.

The present invention is not limited to the above-described embodiment, and includes various modifications. For example, the above-described embodiment has been described in detail in order to explain the present invention in an easy-to-understand manner, and is not necessarily limited to the one including all the described configurations.

1 Impeller 2 Pump casing 3 Fastening part 4 Pump piping 5 Rotating shaft 6 Suction port 7 Discharge port 8 Set part 9 Coupling part 10 Seal part 11 Discharge casing 12 Bearing part 13 Intermediate coupling part 14 Guide blade 15 Support part 16 Reinforcement Rib 17 Discharge flange 20 Avoiding resonance rib 30 Pump 100 Vertical shaft pump

Claims (1)

A pump having an impeller and a pump casing covering the impeller is connected to the pump casing via a fastening portion, and a suction port for sucking a fluid is connected to the pump casing via a fastening portion. The flow direction of the fluid is changed from the vertical direction to the horizontal direction in order to connect the pump pipe for flowing the fluid to the pump pipe via a fastening portion and to circulate the fluid to the discharge port for discharging the fluid. It has a curved portion, a support portion for suspending from a set portion formed in a pump well, a discharge flange formed in the discharge port, and a discharge casing having the same.
A resonance avoiding rib formed between the discharge flange and the support portion so as to suppress the vibration of the discharge casing and connect the vertical pipe and the horizontal pipe of the discharge casing inside the curved portion. Have,
The avoidance resonance rib is characterized in that one is formed at the center of the left-right direction, which is the lower side of the curved portion and is bilateral direction with respect to the discharge direction of the fluid, and a pair is formed symmetrically thereof. Vertical shaft pump.

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