JP6087566B2 - Pump device having dynamic vibration absorber - Google Patents

Description

  The present invention relates to a technique for damping vibration caused by an electric motor for a vertical shaft pump.

  Conventionally, a technique for installing an electric motor for driving a vertical shaft pump on a pedestal is widely known. When this electric motor is driven, vibration is generated, and measures against the vibration may be required. As one of the countermeasures, a method of damping vibration by installing a dynamic vibration absorber is known.

  For example, Patent Document 1 below discloses a technique in which an electric motor base is installed above a vertical shaft pump, and a dynamic vibration absorber is installed above the electric motor installed on the base. Patent Document 2 below discloses a dynamic vibration absorber in which a frame is installed and a swingable weight is installed inside the frame.

JP 2007-32626 A JP-A-3-14094

  However, in the techniques of Patent Documents 1 and 2, it is difficult to install the dynamic vibration absorber unless the surrounding space is sufficiently secured. Specifically, in the technique of Patent Document 1, an installation space for the dynamic vibration absorber is required above the electric motor. Moreover, in the technique of patent document 2, the installation space of the frame for supporting a dynamic vibration absorber is needed. Therefore, a vibration damping technique that can improve the degree of freedom of installation is required. Furthermore, when installing a dynamic vibration absorber, it is desirable to consider the ease of installation of the pump and the electric motor and the ease of maintenance.

  In addition, in an electric motor mount, an inspection port is usually provided for the purpose of connecting a rotary shaft of a pump and a rotary shaft of an electric motor with a shaft coupling. Due to the influence of the inspection port and the anisotropy of the shape of the electric motor, the natural frequencies in the two horizontal directions of the electric motor and the motor mount are often different. When this natural frequency and the rotation speed of the electric motor resonate, vibration increases. For this reason, it is desirable that the dynamic vibration absorber can cope with the horizontal vibration caused by the above-described anisotropy.

  SUMMARY An advantage of some aspects of the invention is to solve at least a part of the problems described above, and the invention can be implemented as, for example, the following forms.

  The 1st form of this invention is provided as a pump apparatus. This pump device is an electric motor that has a first rotary shaft that extends in the vertical direction and a second rotary shaft that extends in the vertical direction, and is disposed above the vertical pump. The lower end of the rotating shaft is installed between the motor connected to the upper end portion of the first rotating shaft, the vertical shaft pump and the electric motor, and the frame that supports the electric motor is installed inside the frame. And a dynamic vibration absorber that attenuates the vibration. The dynamic vibration absorber is an oscillating body having a weight, and is provided with an oscillating body that is suspended while being supported by a gantry and can oscillate in a predetermined direction.

According to such a pump device, the vibration is suitably damped by absorbing the vibration energy in the horizontal direction caused by the operation of the electric motor by the vibration of the oscillator. Further, since the dynamic vibration absorber is installed inside the gantry, it is not necessary to secure an installation space for the dynamic vibration absorber around the motor. Therefore, the installation space of the dynamic vibration absorber is not limited, and the degree of freedom of installation of the dynamic vibration absorber can be improved. Furthermore, according to the dynamic vibration absorber, since the oscillating body is supported by the gantry, it is not necessary to separately provide the oscillating body support. For this reason, it becomes possible to expand a use space.

  As a second aspect of the present invention, in the first aspect, the predetermined direction in which the rocking is possible may be a direction intersecting the vertical direction. According to such a form, it is possible to suitably dampen horizontal vibration caused by the influence of the inspection port of the gantry and the anisotropy of the shape of the electric motor.

  As a third aspect of the present invention, in the second aspect, the dynamic vibration absorber may include springs arranged along a predetermined direction on both sides of the oscillator in a predetermined direction. One end of the spring may be supported by the gantry and the other end may be connected to the rocking body. According to this configuration, the weight is easily swung by the restoring force of the spring, and as a result, absorption of vibration energy by the weight is promoted.

  As a fourth aspect of the present invention, in any of the first to third aspects, the number of weights may be a multiple of two. The number of weights that is a multiple of 2 may be arranged symmetrically with respect to the axes of the first rotation axis and the second rotation axis in a direction intersecting with a predetermined direction in which oscillation is possible. According to this form, the first rotating shaft and the second rotating shaft do not interfere with the weight.

  As a fifth aspect of the present invention, the pump device according to the fourth aspect may include a connection member that connects weights symmetrical about an axis so that the weights swing in the same phase. Good. According to this form, the weights are swung in opposite phases, and the vibration damping effect is not reduced.

  As a sixth aspect of the present invention, the pump device according to the fourth or fifth aspect includes a rotating mechanism capable of rotating the oscillator in the circumferential direction around the axes of the first rotating shaft and the second rotating shaft. And the rocking | fluctuating body may be provided with the rotation mechanism supported by a mount via a rotation mechanism. Furthermore, the pump device may include a fixing member that fixes the position of the rocking body in the direction of rotation. According to such a form, since the rocking body can be rotated and moved, the work inside the gantry can be easily performed. Moreover, it can suppress that a rotation mechanism acts as a spring system, and a vibration damping effect reduces.

  As a seventh aspect of the present invention, in the fourth aspect, the weight is a first weight composed of a number of weights that is a multiple of 2 that can swing in a first direction as a predetermined direction. A weight group and a second weight group composed of weights of multiples of 2 that can swing in a second direction different from the first direction as a predetermined direction. Also good. The weights of the first weight group are arranged symmetrically with respect to the axes of the first rotation axis and the second rotation axis in the direction intersecting the first direction, and the weights of the second weight group May be arranged symmetrically with respect to the axis of the first rotation axis and the second rotation axis in a direction crossing the second direction. The first weight group and the second weight group are arranged at positions that do not overlap in the vertical direction. According to this mode, it is possible to set a plurality of vibration damping countermeasure directions. The fifth or sixth embodiment can also be applied to the seventh embodiment.

It is explanatory drawing which shows schematic structure of the pump apparatus as an Example of this invention. It is an enlarged view of the periphery of a mount. It is explanatory drawing which shows schematic structure of a dynamic vibration absorber. It is explanatory drawing which shows schematic structure of the dynamic vibration damper as 2nd Example. It is explanatory drawing which shows arrangement | positioning of the weight as a modification.

  A. First embodiment:

  FIG. 1 shows a schematic configuration of a pump device 20 as a first embodiment of the present invention. As illustrated, the pump device 20 includes a vertical shaft pump 30, an electric motor 40, and a gantry 50. The vertical shaft pump 30 includes an impeller casing 31, a suspension pipe 32 that suspends the impeller casing 31 in the water tank 90, and a discharge curved pipe 33 that is connected to the upper end of the suspension pipe 32. An impeller (not shown) of the vertical shaft pump 30 is accommodated in the impeller casing 31. The suspension pipe 32 extends downward through an insertion hole 92 formed in the pump installation floor 91 in the upper part of the water tank 90, and is fixed to the pump installation floor 91 via an installation base 93 provided at the upper end of the suspension pipe 32. Is done. The rotary shaft 34 of the vertical shaft 30 extends in the vertical direction into the impeller casing 31 through the discharge bend pipe 33 and the suspension pipe 32.

  The impeller is fixed to the end of the rotating shaft 34 extending in the vertical direction. The impeller casing 31 and the suspension pipe 32 as the pump casing guide the treated water pumped up from the water tank 90 upward in the vertical direction by the rotation of the impeller.

  The electric motor 40 is disposed above the vertical pump 30 as a drive source of the vertical pump 30. The electric motor 40 includes a rotating shaft 44 extending in the vertical direction. The lower end portion of the rotating shaft 44 is coaxially connected to the upper end portion of the rotating shaft 34 of the vertical shaft pump 30 about the axis AL. When the electric motor 40 rotates the rotating shaft 44, the rotational force is transmitted to the rotating shaft 34, and the impeller fixed to the rotating shaft 34 rotates.

  FIG. 2 is an enlarged view of the periphery of the gantry 50. As illustrated, the gantry 50 is installed between the vertical shaft pump 30 and the electric motor 40. The gantry 50 is fixed on a flange 58 provided at the upper end of the vertical shaft pump 30. An electric motor 40 is placed on the top of the gantry 50, and the gantry 50 supports the electric motor 40.

  Inside the gantry 50, the rotary shaft 34 and the rotary shaft 44 are connected via a shaft coupling 60. Inside the gantry 50, a space SP is formed around the rotating shaft 34, the rotating shaft 44, and the shaft coupling 60 in the circumferential direction of the axis AL. In this space SP, the motor 40 and a dynamic vibration absorber 100 for attenuating vibration (resonance) of the gantry 50 are installed (not shown in FIG. 2). The gantry 50 is provided with an inspection port 55 at a predetermined position. The inspection port 55 is used for work for connecting the rotating shaft 34 and the rotating shaft 44 by the shaft coupling 60, maintenance of the shaft coupling 60, and the like.

  FIG. 3 shows a schematic configuration of the dynamic vibration absorber 100 provided in the space SP inside the gantry 50. FIG. 3A shows a side view of the dynamic vibration absorber 100. FIG. 3B shows a top view of the dynamic vibration absorber 100. In FIG. 3B, in order to make the drawing easier to see, some of the components (springs 160 and 170, bearing unit 123, etc.) are not shown. In FIG. 3 (A), the trunk | drum 51 of the mount frame 50 is shown by the cross section. In FIG. 3B, the rotating shaft 44 is shown in cross section. As shown in FIG. 3A, the gantry 50 includes a trunk portion 51 extending in the vertical direction. The trunk | drum 51 has a substantially ring-shaped cross section. As shown in FIGS. 3A and 3B, four mounting seats 52 that protrude inward from the inner surface of the trunk portion 51 are provided above the trunk portion 51. Further, four mounting seats 53 projecting inward from the inner surface of the body portion 51 are provided below the mounting seat 52 in the vertical direction.

  As shown in FIGS. 3 (A) and 3 (B), the dynamic vibration absorber 100 is installed inside the gantry 50, and includes an oscillating body 110, two sets of springs 160 and 170, and two support portions 180. Is provided. The oscillator 110 includes two upper seat plates 121, two lower seat plates 122, two bearing units 123, weights 140 and 150, two screw rods 131, and two sets of guide rods 132 and 133. Is provided. Each of the support portions 180 includes a support plate 181 and a bearing portion 182. In FIG. 3A, only one upper seat plate 121, lower seat plate 122, bearing unit 123, screw rod 131, support plate 181 and bearing portion 182 are shown. Similarly, in FIG. 3A, only one set of guide bars 132 and 133 is shown. Similarly, in FIG. 3A, only the weight 140 is shown, and the weight 150 is not shown.

  As shown in FIG. 3A, the upper seat plate 121 and the lower seat plate 122 are plate-like members extending along a predetermined direction D1 that intersects (in this case, orthogonal) with the vertical direction, and are separated in the vertical direction. Provided. The upper seat plate 121 and the lower seat plate 122 are connected by a screw rod 131 and guide rods 132 and 133 extending in the vertical direction. The screw rod 131 and the guide rods 132 and 133 are inserted into through holes provided in the weights 140 and 150. The weights 140 and 150 are guided in the vertical direction by the guide rods 132 and 133 and can be moved in the vertical direction. The vertical positions are fixed by tightening the nuts 134 and 135 at the desired vertical positions. The The natural frequency can be adjusted by changing the vertical positions of the weights 140 and 150. A bearing unit 123 is attached to the upper portion of the upper seat plate 121.

  As shown in FIG. 3B, the two upper seat plates 121 are connected by two connecting members 191 and 192 having rigidity. The connecting members 191 and 192 are arranged symmetrically with respect to the axis AL in a direction intersecting the predetermined direction D1 (here, a direction orthogonal).

  In this embodiment, the weights 140 and 150 have a substantially rectangular parallelepiped shape. As shown in FIG. 3B, the two weights 140 and 150 are arranged symmetrically with respect to the axis AL in a direction intersecting the predetermined direction D1 (here, a direction orthogonal). That is, the weights 140 and 150 are disposed so as to face each other with the axis AL interposed therebetween (center).

  Each of the support plates 181 is formed so as to extend along the predetermined direction D1, and both ends thereof are placed and fixed on the two mounting seats 52, respectively. A bearing portion 182 provided at the center of the support plate 181 supports the shaft 183. The shaft 183 passes through the bearing unit 123 provided in the bearing portion 182 and is engaged with the bearing unit 123. That is, the oscillating body 110 is suspended while being supported by the gantry 50, and is configured to be able to oscillate in a predetermined direction D1 with the shaft 183 as a rotation axis. Since the two upper seat plates 121 are connected by the connecting members 191 and 192, the weights 140 and 150 swing at the same phase.

  As shown in FIG. 3A, two sets of springs 160 and 170 are connected to the rocking body 110. The springs 160 and 170 are leaf springs in this embodiment. The springs 160 and 170 are disposed on both sides of the rocking body 110 in the predetermined direction D1 along the predetermined direction D1, that is, along the rocking direction of the rocking body 110. One end of each of the springs 160 and 170 is fixed on the four mounting seats 53 and supported by the gantry 50. The other ends of the pair of springs 160 and 170 are connected to the side surface of the weight 140, respectively, and the other ends of the other set of springs 160 and 170 are connected to the side surface of the weight 150, respectively. The other ends of the springs 160 and 170 do not necessarily need to be connected to the weights 140 and 150, but may be connected to the oscillator 110. For example, the springs 160 and 170 may be connected to the lower seat plate 122. Of course, the springs 160 and 170 have an arbitrary configuration and can be omitted.

As shown in FIG. 3B, in the gantry 50, the inspection port 55 is provided between the weight 140 and the weight 150 in a direction orthogonal to the predetermined direction D1. That is, when the inspection port 55 is opened, the weights 140 and 150 are provided on the front surface. Thereby, the worker can easily enter from the inspection port 55 to the vicinity of the shaft coupling 60. In addition, since the operator can enter the gantry 50 between the weight 140 and the weight 150 along the predetermined direction D1 in which the weights 140 and 150 swing, the worker temporarily assumes the inspection port 55. Even when the weights 140 and 150 are swung for some reason (for example, an earthquake) when entering the gantry 50 from the inside, safety can be ensured.

  According to the dynamic vibration absorber 100, the vibration is suitably damped by absorbing the vibration in the horizontal direction caused by the operation of the electric motor 40 by the vibration of the weights 140 and 150. In addition, since the weights 140 and 150 swing in a predetermined direction D1 intersecting the vertical direction, horizontal vibrations caused by the influence of the inspection port 55 of the gantry 50 and the anisotropy of the shape of the electric motor 40 are prevented. It can be suitably attenuated. Further, in the dynamic vibration absorber 100, the weights 140 and 150 are easily swung by the restoring force of the springs 160 and 170, and as a result, absorption of vibration energy by the weights 140 and 150 is promoted.

  In addition, since the dynamic vibration absorber 100 is installed inside the gantry 50, it is not necessary to secure an installation space for the dynamic vibration absorber 100 around the electric motor 40. Therefore, the installation space of the dynamic vibration absorber 100 is not limited, and the degree of freedom of installation of the dynamic vibration absorber 100 can be improved. The inside of the gantry 50 is normally not used except for inspection work and is a dead space. However, according to the present embodiment, the dead space can be effectively used. Further, since the swing of the swing body 110 is isolated from the outside by the gantry 50, the safety is high. Furthermore, it can suppress that the rotation failure of the axis | shaft 183, etc. arise by a dust. The installation of the dynamic vibration absorber 100 does not affect the appearance of the vertical shaft pump 30, the electric motor 40, and the gantry 50.

  Moreover, according to the dynamic vibration absorber 100, since the rocking | swiveling body 110 is supported by the mount frame 50, it is not necessary to provide the support body of the rocking body 110 separately. For this reason, it becomes possible to expand a use space. That is, the freedom degree of arrangement | positioning of the rocking | swiveling body 110 improves, and the utilization range of space spreads. The dynamic vibration absorber 100 does not include a casing frame that accommodates the dynamic vibration absorber 100. That is, in the configuration of the present embodiment, the gantry 50 is used as the casing frame of the dynamic vibration absorber 100. In this way, by using both the gantry 50 and the casing frame of the dynamic vibration absorber 100, the range of utilization of the space in the gantry 50 is expanded. For example, compared with the case where the casing frame of the dynamic vibration absorber 100 is provided separately, the weights 140 and 150 can be enlarged, and as a result, the damping effect of vibration can be enhanced.

  The dynamic vibration absorber 100 can be easily installed from above in the vertical direction by removing the electric motor 40 installed on the gantry 50. For this reason, it can be easily applied to an existing pump device.

  Further, the weight is divided into the weight 140 and the weight 150 and arranged symmetrically with respect to the axis AL in the direction intersecting the predetermined direction D1, that is, facing the axis AL in between. Therefore, even if the rotating shaft 34, the rotating shaft 44, and the shaft coupling 60 are located in the center of the dynamic vibration absorber 100, these do not interfere with the weights 140 and 150. Further, since the weights 140 and 150 are connected by the connecting members 191 and 192 and swing in the same phase, they do not swing in the opposite phase and the vibration damping effect is not reduced.

B. Second embodiment:
FIG. 4 shows a schematic configuration of a dynamic vibration absorber 200 as a second embodiment of the present invention. 4 corresponds to FIG. 3 described above. In FIG. 4, the same reference numerals as those in FIG. 3 are assigned to the same components as those of the dynamic vibration absorber 100 illustrated in FIG. 3. . Hereinafter, only differences from the first embodiment (FIG. 3) will be described, and description of the same points as in the first embodiment will be omitted.

  As shown in FIG. 4A, the dynamic vibration absorber 200 as the second embodiment includes a mounting seat 252 instead of the mounting seat 52. As shown in FIG. 4B, the mounting seat 252 has a ring shape that protrudes inward from the inner surface of the body portion 51 and is continuously provided in the circumferential direction along the inner surface of the body portion 51. . As shown in FIG. 4A, a guide groove 254 is formed above the mounting seat 252 in the vertical direction.

  Further, as shown in FIGS. 4A and 4B, a rotation mechanism 285 is attached to each end of the two support plates 181 on the lower surface in the vertical direction. The rotation mechanism 285 is a caster in this embodiment. The support portion 180 is placed on the mounting seat 252 such that the rotation mechanism 285 is positioned inside the guide groove 254 formed in the mounting seat 252. At this time, the oscillator 110 is supported by the gantry 50 via the rotation mechanism 285. According to this configuration, the rocking body 110 and the support portion 180 can be rotated in the circumferential direction around the axis AL.

  Accordingly, when the operator enters the inside of the gantry 50 through the inspection port 55 and performs work, the operator moves the oscillating body 110 to a desired position, that is, a position where the oscillating body 110 can easily enter the inside of the gantry 50, or the The rocking body 110 can be rotated to a position where it is easy to work inside. For this reason, the connection and inspection work of the rotating shaft 34 and the rotating shaft 44 is facilitated. Further, it is easy to adjust the vertical position of the weights 140 and 150. From the viewpoint of increasing the rigidity of the gantry 50 and from the viewpoint of safety, the position and opening area of the inspection port 55 are often limited, but according to the configuration of the present embodiment, the inspection port 55 and its There is no difficulty in positioning with the dynamic vibration absorber 200 installed inside.

  Further, according to such a configuration, the installation work of the dynamic vibration absorber 200 can be easily performed. For example, when the predetermined direction D1, that is, the vibration damping countermeasure direction is determined in advance, the mounting seat 53 is set in advance at a predetermined position, and the oscillator 110 is rotated to an appropriate position. The springs 160 and 170 can be fixed. Alternatively, if the mounting seat 53 is continuously formed in a ring shape in the circumferential direction, the springs 160 and 170 can be fixed at the arbitrary position after the rocking body 110 is rotated to an arbitrary desired position. . In this way, the countermeasure direction can be corrected according to the state of occurrence of vibration.

  In the dynamic vibration absorber 200, the rocking body 110 rotated to a desired position may be fixed so as not to rotate by a fixing member that fixes the position. As such a fixing member, for example, a jack bolt can be used. Alternatively, a clamp or the like attached to the mounting seat 252 may be arranged on both sides of the rotation mechanism 285 so that the position of the rotation mechanism 285 cannot be moved and the position of the rocking body 110 may be fixed. With this configuration, since the position of the rotation mechanism 285 is fixed, it is possible to suppress the rotation mechanism 285 from acting as a spring system and reducing the vibration damping effect.

C. Variations:
C-1. Modification 1:
The dynamic vibration absorbers 100 and 200 may include a damper that further attenuates vibration. As such a damper, for example, a friction damper, a magnetic damper, or the like can be used.

C-2. Modification 2:
The weight is not necessarily divided into two parts, and may be one weight having a space penetrating in the direction of the axis AL. In this case, the rotating shaft 34 and the rotating shaft 44 are accommodated in the space. Further, the space is formed with a sufficient size so as not to interfere with the rotating shaft 34 and the rotating shaft 44 when the weight swings.

C-3. Modification 3:
The number of weights is not limited to two, and can be an arbitrary multiple of two. For example, the weights 140 and 150 may be further divided into two in the predetermined direction D1. Specifically, two weights may be arranged side by side in the predetermined direction D1 between the pair of upper seat plate 121 and lower seat plate 122. In this case, by providing a gap between the two weights, it is possible to improve the workability of maintenance and management of workers.

  Alternatively, the weight can swing in the first predetermined direction D1, and can be in a second predetermined direction D2 that is different from the predetermined direction D1 and a first weight group composed of a number of weights that is a multiple of two. And a second weight group composed of a number of weights that is a multiple of 2 that can be swung.

  FIG. 5 shows a specific example of the arrangement of such weights. The weights 140 and 150 can swing in the first predetermined direction D1, and the weights 340 and 350 can swing in the second predetermined direction D2. In the illustrated example, the first predetermined direction D1 and the second predetermined direction D2 are directions orthogonal to each other. The weights 140 and 150 are arranged symmetrically with respect to the axis AL in the direction intersecting the first predetermined direction D1 (here, the second predetermined direction D2), and the weights 340 and 350 are the second predetermined direction. In a direction crossing the direction D2 (here, the first predetermined direction D1), they are arranged symmetrically with respect to the axis AL. Furthermore, the weights 140 and 150 and the weights 340 and 350 are arranged in positions that do not overlap in the vertical direction, that is, positions that do not interfere with each other when the weights oscillate. Yes. According to such a configuration, a plurality of vibration damping countermeasure directions can be set.

C-4. Modification 4:
In the above-described embodiment, as the dynamic vibration absorbers 100 and 200, the suspension type in which the rocking body 110 is supported by the gantry 50 and suspended in a predetermined direction D1 is exemplified. Can adopt any type that can swing in a predetermined direction while the swinging body is supported by the gantry. For example, the dynamic vibration absorber may have the following configuration. This dynamic vibration absorber includes an oscillating body (weight) and a spring element. The rocking body is provided at a position where it does not interfere with the vertical shaft pump and the rotating shaft of the electric motor. The spring element is formed extending in the vertical direction. The upper end of the spring element is fixed to a gantry (a protruding portion protruding inward from the gantry), and the lower end is fixed to the swinging body below the protruding portion. That is, the rocking body is suspended from the gantry via the spring element. With this configuration, the swinging body is configured to be swingable in the vertical direction while being supported by the gantry.

C-5. Modification 5:
The dynamic vibration absorbers 100 and 200 may be installed in a casing frame provided separately from the gantry 50. That is, for example, the following configuration may be used. Each component of the dynamic vibration absorber 100 is accommodated in a casing frame. The rocking body 110 is supported by the casing frame in a manner supported by the gantry 50 in the above-described embodiment. One ends of the springs 160 and 170 are fixed to the casing frame. The casing frame is supported by the gantry 50. For example, a flange portion may be provided on the outer edge of the casing frame, and the flange portion may be placed on and fixed to the mounting seat of the gantry 50 (corresponding to the mounting seat 52 described above). Alternatively, a support member may be placed and fixed on the mounting seat of the gantry 50, and a casing frame that houses the dynamic vibration absorber 100 may be suspended from the support member. In this case, it is desirable that the casing frame is suspended in a manner that does not swing. According to this aspect, the safety when working inside the gantry 50 is improved. Even in these cases, the rocking body 110 can be regarded as being indirectly supported by the gantry 50 via the casing frame.

  When the casing frame is thus provided, the casing frame is provided at a position where it does not interfere with the rotating shafts 34 and 44 and the shaft coupling 60. For example, two casing frames that respectively accommodate the dynamic vibration absorbers 100 may be arranged at positions where the weights 140 and 150 are provided in the first embodiment. Further, since the components of the dynamic vibration absorber 100 do not interfere with the rotating shafts 34 and 44 and the shaft coupling 60 in the casing frame, the weight can be freely arranged in the casing frame. For example, one weight may be arranged at the center on the horizontal plane in the casing frame.

  The embodiments of the present invention have been described above based on some examples. However, the above-described embodiments of the present invention are for facilitating the understanding of the present invention and limit the present invention. It is not a thing. The present invention can be changed and improved without departing from the gist thereof, and the present invention includes the equivalents thereof. Moreover, in the range which can solve at least one part of the subject mentioned above, or the range which exhibits at least one part of an effect, the combination of each component described in the claim and the specification, or omission is possible. .

DESCRIPTION OF SYMBOLS 20 ... Pump apparatus 30 ... Vertical shaft pump 31 ... Impeller casing 32 ... Suspension pipe 33 ... Discharge curved pipe 34 ... Rotating shaft 40 ... Electric motor 44 ... Rotating shaft 50 ... Base 51 ... Body 52, 53, 252 ... Mounting seat 55 ... Inspection port 58 ... Flange 60 ... Shaft coupling 90 ... Water tank 91 ... Pump installation floor 92 ... Insertion hole 93 ... Installation base 100, 200 ... Dynamic vibration absorber 110 ... Oscillator 121 ... Upper seat plate 122 ... Lower seat plate 123 ... Bearing unit 131 ... Screw rod 132 ... Guide rod 134, 135 ... Nut 140, 150, 340, 350 ... Weight 160, 170 ... Spring 180 ... Support portion 181 ... Support plate 182 ... Bearing portion 183 ... Shaft 191, 192 ... Connecting member 254 ... Guide groove 285 ... Rotation mechanism AL ... Axis SP ... Space D1 ... Predetermined direction (first predetermined direction)
D2 ... Second predetermined direction

Claims (4)

A pump device,
A vertical pump having a first rotating shaft extending in the vertical direction;
An electric motor having a second rotating shaft extending in the vertical direction and disposed above the vertical pump, wherein a lower end portion of the second rotating shaft is an upper end portion of the first rotating shaft. Connected motor,
A stand that is installed between the vertical shaft pump and the electric motor and supports the electric motor;
A dynamic vibration absorber installed inside the gantry and dampening vibrations of the electric motor,
The dynamic vibration absorber is an oscillating body having a weight, and includes an oscillating body capable of oscillating in a predetermined direction while being supported by the gantry .
The number of weights is a multiple of two;
The weights of the multiple of 2 are arranged symmetrically with respect to the axis of the first rotation axis and the second rotation axis in a direction intersecting with the predetermined direction,
The pump device is
The oscillating body is a rotating mechanism capable of rotating in the circumferential direction around the axes of the first rotating shaft and the second rotating shaft, and the oscillating body is supported by the gantry via the rotating mechanism. A rotating mechanism,
And a fixing member that fixes a position of the rocking body in the rotation direction .   A pump device,
  A vertical pump having a first rotating shaft extending in the vertical direction;
  An electric motor having a second rotating shaft extending in the vertical direction and disposed above the vertical pump, wherein a lower end portion of the second rotating shaft is an upper end portion of the first rotating shaft. Connected motor,
  A stand that is installed between the vertical shaft pump and the electric motor and supports the electric motor;
  A dynamic vibration absorber installed inside the gantry to damp vibrations of the electric motor;
  With
  The dynamic vibration absorber is an oscillating body having a weight, and includes an oscillating body capable of oscillating in a predetermined direction while being supported by the gantry.
  The pump device is
  A connecting member that connects the weights symmetrical with respect to the axis so that the weights swing in the same phase;
  The oscillating body is a rotating mechanism capable of rotating in the circumferential direction around the axes of the first rotating shaft and the second rotating shaft, and the oscillating body is supported by the gantry via the rotating mechanism. Rotating mechanism,
  And a fixing member that fixes the position of the rocking body in the direction of rotation.
  Pump device. The pump device according to claim 1 or 2 ,
The said predetermined direction is a direction which cross | intersects a perpendicular direction Pump apparatus. The pump device according to claim 3 ,
The dynamic vibration absorber includes springs arranged along the predetermined direction on both sides of the oscillator in the predetermined direction,
The oscillating body is suspended while being supported by the gantry,
One end of the spring is supported by the gantry, and the other end is connected to the oscillator.

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