JP2021161875A - Pump device, water supply device, and pump device maintenance method - Google Patents

Abstract

To provide a pump device which enables maintenance work to be easily performed without being subject to limitations on an installation environment.SOLUTION: A pump device 1 includes: an impeller 6; a rotary shaft 10; and a casing assembly 250. The casing assembly 250 includes: a suction flange 200 which extends perpendicularly to an axial direction of the rotary shaft 10 and has an annular shape; and a pump casing 7 connected to the suction flange 200.SELECTED DRAWING: Figure 7

Description

The present invention relates to a pump device, a water supply device, and a method for maintaining the pump device.

A pump device including a pump and a motor is known (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 7-224781

To perform maintenance work on the components of the pumping device, the operator may pull the motor out of the pump. In a typical pump device, the impeller is housed in a cylindrical pump casing. Therefore, when the motor is pulled out, the operator pulls out the motor in the axial direction of the pump casing with all the fasteners for fastening the pump casing and the motor removed. Such pulling work is called back pullout. In order to perform back pull out, it is necessary to provide a space behind the motor for performing back pull out. As a result, the pumping device must be installed in a relatively large space.

However, the pumping device should be installed along the walls of a building, in an underground space, or in a place where there is a structure (such as a wall in a building or underground space, a water tank, etc.) that is an obstacle in the immediate vicinity, such as a space under or beside a water tank. May be requested to install. Therefore, it is desired to provide a pump device capable of performing maintenance work even in such an installation environment.

Therefore, an object of the present invention is to provide a pump device, a water supply device, and a maintenance method for the pump device, which can easily perform maintenance work without being restricted by the installation environment.

In one aspect, a pump device comprising an impeller, a rotating shaft to which the impeller is fixed, and a casing assembly accommodating the impeller is provided. The casing assembly includes a suction flange having a suction port that can be connected to a suction pipe and having an annular shape extending perpendicular to the axial direction of the rotation axis, and a pump casing connected to the suction flange. Be prepared.

In one aspect, the suction flange has a casing contact surface that is in contact with the pump casing and extends parallel to the end wall of the pump casing, the suction flange having only the casing contact surface of the pump casing. It is connected to the suction casing in a state of being in contact with the end wall of the pump.
In one aspect, the casing assembly comprises a flange supporter that supports the suction flange, which has a threaded hole into which a fastener can be inserted through a through hole formed in the flange supporter. ing.
In one aspect, the pumping device comprises a stator and a rotor that rotate the rotating shaft, a motor casing that houses the stator and the rotor, and a fastening member that fastens the casing assembly and the motor casing. , The fastening member extends through the casing assembly and is inserted into an insertion hole formed in the motor casing.

In one aspect, the suction flange is made of resin or metal.
In one aspect, the pump casing has a discharge port that can be connected to the discharge pipe, and the pump device includes a discharge pipe supporter that supports the discharge pipe.

In one aspect, a water supply device including the pump device and a control panel provided with an operation panel is provided. The operation panel is arranged so as to face the same direction as the pull-out direction of the pump casing.

In one aspect, a maintenance method for the pump device is provided. With the suction pipe connected to the suction flange, the operation of the pump device is stopped, the connection between the pump casing and the suction flange is released, and the pump casing is pulled out to the side of the suction flange. ..

In one aspect, the step of pulling out the pump casing to the side of the suction flange is performed in a state where the suction flange is supported by a flange supporter that supports the suction flange.
In one aspect, the step of pulling out the pump casing to the side of the suction flange is performed in a state where the discharge pipe is supported by a discharge pipe supporter that supports the discharge pipe connected to the discharge port of the pump casing. It is said.

The pump device includes a suction flange and a pump casing connected to the suction flange so that it can be pulled out to the side of the suction flange. Therefore, the movement of the pump casing in the side pull-out direction is not hindered by the suction flange, and the pump casing can be easily pulled out in the side pull-out direction. As a result, the pumping device allows the operator to easily perform maintenance work without being constrained by the installation environment.

It is a figure which shows one Embodiment of a pump device. It is a figure which shows the perspective view of the pump device connected to a suction pipe and a discharge pipe. It is a figure which shows the suction flange connected to the suction casing. It is a figure which shows the flange supporter which supports a suction flange. It is a perspective view which shows the water supply device which includes the pump device which concerns on embodiment shown in FIG. It is a figure which shows the discharge pipe supporter which supports a discharge pipe. It is a figure which shows the pump casing and the motor pulled out in the side pull-out direction. It is an enlarged view of the intermediate casing. It is a figure seen from the A line direction of FIG. It is a figure seen from the B line direction of FIG. It is sectional drawing which shows the fitting structure of a pump casing. It is a figure which shows the comparative example for demonstrating the effect of the intermediate casing which concerns on this embodiment. It is a figure for demonstrating the effect of the intermediate casing which concerns on this embodiment. It is a figure which shows the partition member. It is an enlarged view of the seal structure shown in FIG. It is a figure which shows the other embodiment of a seal structure. It is a figure which shows the other embodiment of a pump device. It is a figure which shows still another embodiment of a pump device.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the drawings described below, the same or corresponding components are designated by the same reference numerals, and duplicate description will be omitted. In the plurality of embodiments described below, the configuration of one embodiment not particularly described is the same as that of the other embodiments, and thus the duplicated description will be omitted.

FIG. 1 is a diagram showing an embodiment of the pump device 1. As shown in FIG. 1, the pump device 1 which is an example of a mechanical device includes a pump 2 which is an example of a rotary machine that transfers a fluid (in this embodiment, a liquid) and a motor (motor) 3 which operates the pump 2. It is a mechanical device including. In the present embodiment, the pump 2 is a horizontal axis multi-stage pump. The pump 2 includes a rotating shaft 10, a plurality of impellers 6A to 6C fixed to the rotating shaft 10 (in this embodiment, three stages), a pump casing 7 accommodating the plurality of impellers 6A to 6C, and a pump casing 7. It includes a suction flange 200 that is detachably connected to the pump casing 7. Hereinafter, the pump casing 7 may be simply referred to as a casing.

The rotating shaft 10 is connected to a motor 3 as a drive source. The motor 3 rotates the rotating shaft 10 by its drive. The impellers 6A to 6C rotate together with the rotating shaft 10. The motor 3 includes a rotor 11 fixed to a rotating shaft 10, a stator 12 arranged so as to surround the rotor 11, and a motor casing accommodating the rotor 11 and the stator 12. 13 and. The stator 12 is fixed to the inner peripheral surface of the motor casing 13. The rotor 11 and the stator 12 are rotating elements.

In one embodiment, the motor 3 may be provided with inverters (not shown) arranged in series along the axis CL direction of the rotating shaft 10. The combination of the motor 3 and the inverter is called an electric motor assembly. In this case, the pump device 1 is a mechanical device including the pump 2 and the motor assembly.

The combination of the pump casing 7 and the suction flange 200 is the casing assembly 250. The pump casing 7 includes a suction casing 16 connected to a suction flange 200, a discharge casing 18 having a discharge port 17, and an intermediate casing 20 arranged between the suction casing 16 and the discharge casing 18. ..

As shown in FIG. 1, the suction flange 200, the suction casing 16, the intermediate casing 20, and the discharge casing 18 are arranged in series in this order. The suction flange 200 has a suction port 15 that opens in the axis CL direction of the rotating shaft 10, and the discharge port 17 of the discharge casing 18 opens in a direction perpendicular to the axis CL direction.

In the embodiment shown in FIG. 1, the impeller 6A is housed in the suction casing 16, the impeller 6B is housed in the intermediate casing 20, and the impeller 6C is housed in the discharge casing 18. When the impellers 6A to 6C fixed to the rotating shaft 10 rotate, the liquid is introduced into the pump casing 7 through the suction port 15 of the suction flange 200. The liquid introduced into the pump casing 7 is stepwise boosted by the impellers 6A to 6C and transferred to the outside of the pump 2 through the discharge port 17. Hereinafter, the impellers 6A to 6C may be simply referred to as impellers 6 without distinction. The impeller 6 may be made of resin or metal.

FIG. 2 is a perspective view of a pump device 1 connected to a suction pipe P1 and a discharge pipe P2. As shown in FIG. 2, the suction port 15 of the suction flange 200 is connected to the suction pipe P1, and the discharge port 17 of the discharge casing 18 is connected to the discharge pipe P2. The pump device 1 is arranged on the base B. More specifically, the motor 3 is supported by the motor supporter 205 fixed to the base B, and the pump casing 7 is supported by the flange supporter 215 via the suction flange 200. Details of the configuration of the flange supporter 215 will be described later.

As shown in FIG. 2, the suction flange 200 is formed with a plurality of reinforcing ribs 201 for improving the rigidity of the suction flange 200. The plurality of reinforcing ribs 201 are arranged at equal intervals along the circumferential direction of the suction flange 200, and extend radially in the radial direction of the suction flange 200. The number of reinforcing ribs 201 is not limited to this embodiment.

FIG. 3 is a diagram showing a suction flange 200 connected to the suction casing 16. Note that in FIG. 3, the reinforcing rib 201 is not shown. The suction flange 200 is made of a member (metal (for example, stainless steel) or resin) having an annular shape extending perpendicularly to the axis CL direction of the rotating shaft 10. The suction flange 200 has a main body 210 on which the reinforcing rib 201 is formed, and a suction port 211 projecting from the main body 210.

The main body 210 and the suction port 211 are integrally molded members and are arranged concentrically with the rotating shaft 10. The suction flange 200 has a suction port side surface (first surface) 200a on which the reinforcing rib 201 is formed, and a casing contact surface (second surface) 200b on the side opposite to the first surface 200a. .. The first surface 200a and the second surface 200b are both end surfaces of the main body 210.

As shown in FIGS. 2 and 3, the suction flange 200 is fastened to the pump casing 7 (more specifically, the suction casing 16) by a plurality of fastening members (for example, through bolts) 8. In the embodiment shown in FIG. 2, four fastening members 8 are drawn, but the number of fastening members 8 is not limited to the embodiment shown in FIG.

The fastening member 8 fastens the casing assembly 250 (that is, the pump casing 7 and the suction flange 200) and the motor casing 13. More specifically, as shown in FIG. 1, the fastening member 8 extends through the suction flange 200, the suction casing 16, the intermediate casing 20, and the discharge casing 18, and is inserted into the motor casing 13. .. The motor casing 13 is made of a metal member and has an insertion hole 13a into which the fastening member 8 is inserted. The insertion hole 13a is formed with a thread groove (not shown) into which the fastening member 8 can be screwed.

With such a configuration, the operator arranges the suction casing 16, the intermediate casing 20, and the discharge casing 18 in this order between the suction flange 200 and the motor casing 13, and in this state, the fastening member 8 is attached to the motor casing. It is inserted into the insertion hole 13a of 13. After that, the operator tightens the fastening member 8, so that the suction flange 200, the suction casing 16, the intermediate casing 20, the discharge casing 18, and the motor casing 13 are firmly fastened to each other. In the present embodiment, the fastening member 8 is screwed into the insertion hole 13a formed in the metal motor casing 13. With such a configuration, the fastening member 8 can be strongly tightened, and as a result, the number of fastening members 8 can be reduced.

As shown in FIG. 3, the suction casing 16 has an end wall 19 that is in close contact with the suction flange 200. The end wall 19 has a communication hole 19a formed in the center thereof. The communication hole 19a communicates with the suction port 15 of the suction flange 200 and has a diameter larger than the diameter of the suction port 15. An annular seal groove 203 on which a seal member 202 such as an O-ring is mounted is formed on the second surface (that is, the casing contact surface) 200b of the suction flange 200. The seal groove 203 is arranged concentrically with the rotating shaft 10. When the suction flange 200 is fastened to the suction casing 16 by the fastening member 8, the seal member 202 is compressed by the second surface 200b of the suction flange 200 and the end wall 19 of the suction casing 16. As a result, the sealing member 202 can prevent the liquid from leaking from between the suction flange 200 and the suction casing 16.

By forming the suction flange 200 to which the suction pipe P1 is connected made of metal, the following effects can be obtained. A large load of the suction pipe P1 acts on the suction flange 200, but the metal suction flange 200 has a strength capable of withstanding the large load of the suction pipe P1. Therefore, troubles such as disconnection of the suction pipe P1 from the pump device 1 and deformation or breakage of the suction pipe P1 can be prevented, and as a result, the pump device 1 can be operated safely.

FIG. 4 is a diagram showing a flange supporter 215 that supports the suction flange 200. As shown in FIGS. 2 and 4, the pump device 1 (more specifically, the casing assembly 250) may further include a flange supporter 215 that supports the suction flange 200. As shown in FIG. 4, the flange supporter 215 has an L-shaped cross-sectional shape.

The flange supporter 215 has a suction flange side portion 215a connected to the suction flange 200, a base side portion 215b connected to the base B, and a connection portion 215c connecting the suction flange side portion 215a and the base side portion 215b. Have. The suction flange side portion 215a and the suction flange 200 are fastened by the fastener 216, and the base side portion 215b and the base B are fastened by the fastener 217. More specifically, the suction flange 200 has a screw hole 219 into which the fastener 216 can be inserted through the through hole 218 formed in the flange supporter 215.

The screw hole 219 is formed with a screw groove (not shown) into which the fastener 216 can be screwed. Therefore, the operator inserts the fastener 216 into the screw hole 219 of the suction flange 200 through the through hole 218 of the flange supporter 215 and tightens the fastener 216 to fasten the flange supporter 215 and the suction flange 200 to each other. .. As a result, the flange supporter 215 supports the suction flange 200. In this way, the flange supporter 215 can receive the load of the suction pipe P1 via the suction flange 200.

FIG. 5 is a perspective view showing a water supply device 300 including the pump device 1 according to the embodiment shown in FIG. As shown in FIG. 5, the water supply device 300 controls the operation of a plurality of (two in FIG. 5) pump devices 1, a base B on which the plurality of pump devices 1 are mounted, and the pump device 1. It includes a control panel 301 and a support member 302 that supports the control panel 301. The control panel 301 is provided with an operation panel 312. In FIG. 5, the operation panel 312 is arranged so as to face the rear of the motor 3.

Here, as shown in FIG. 5, the front side of the pump device 1 is defined as "front", the rear side of the pump device 1 is defined as "rear", and the lateral side of the pump device 1 is defined with reference to the pump device 1. Is defined as "side". Therefore, the rear side of the motor 3 means the position on the rear side of the motor 3.

The control panel 301 is supported by a support member 302 extending above the motor 3, and is arranged above the motor 3. The support member 302 includes a leg portion 302a fixed to the base B and extending upward from the surface of the base B, and a gantry 302b fixed to the leg portion 302a and on which the control panel 301 is placed. There is. The gantry 302b extends in a direction parallel to the surface of the base B (that is, in the horizontal direction), and has a size on which the control panel 301 can be placed. The gantry 302b has a wide shape extending parallel to the longitudinal direction of the base B. Here, the longitudinal direction of the base B is defined as a direction perpendicular to the width direction of the base B. The width direction of the base B is defined as a direction parallel to the axis CL direction of the rotation axis 10.

In the embodiment shown in FIG. 5, the pump casing 7 and the motor 3 can be pulled out in a direction perpendicular to the radial direction of the suction flange 200, that is, in the rearward direction (back pullout direction) of the motor 3. Further, the pump casing 7 and the motor 3 can be pulled out in the radial direction of the suction flange 200, that is, in the side (side pull-out direction) of the motor 3. The radial direction of the suction flange 200 is a direction perpendicular to the axis CL direction, in other words, a direction parallel to the longitudinal direction of the base B.

When the operator pulls out the pump casing 7 and the motor 3 in the back pull-out direction, the control panel 301 is preferably arranged so that the operation panel 312 faces the rear of the motor 3. In this case, the operator can operate the operation panel 312 at the position behind the motor 3 and can pull out the pump casing 7 and the motor 3 in the back pull-out direction at the position behind the motor 3. ..

The pump casing 7 and the motor 3 are pulled out with the suction flange 200 connected to the suction pipe P1. More specifically, the operator stops the operation of the pump device 1, removes the fastening member 8 while the suction flange 200 is supported by the flange supporter 215, and separates the pump casing 7 from the suction flange 200. .. By such an operation, the operator can pull out the pump casing 7 and the motor 3 in the back pull-out direction while the suction pipe P1 is supported by the flange supporter 215 via the suction flange 200.

According to the present embodiment, the pump casing 7 and the motor 3 can be pulled out by a simple method of simply removing the fastening member 8 without removing the suction flange 200 from the suction pipe P1, so that the operator can pull out the pump casing. The maintenance work of the 7 and the motor 3 can be easily performed.

The fastening member 8 penetrates the suction flange 200 and the pump casing 7 and is fastened to the motor casing 13, while the fastener 216 extends through the flange supporter 215 and is fastened to the suction flange 200. There is. Therefore, the flange supporter 215 can continue to support the suction flange 200 unless the fastener 216 is removed. Therefore, the operator can pull out the pump casing 7 and the motor 3 while supporting the suction flange 200 with the flange supporter 215 by removing the fastening member 8 while leaving the fastener 216.

Even if the pump casing 7 and the motor 3 are pulled out, the suction pipe P1 is supported by the flange supporter 215 via the suction flange 200, so that the suction pipe P1 is separated from the suction flange 200 and the suction pipe P1 is deformed. , It is possible to prevent the occurrence of troubles such as damage.

FIG. 6 is a diagram showing a discharge pipe supporter 100 that supports the discharge pipe P2. In the embodiment shown in FIG. 6, the discharge pipe supporter 100 is a rod member extending upward from the base B and supports the discharge pipe P2. The discharge pipe supporter 100 is arranged between the two pump casings 7 independently of the pump casings 7. Therefore, even if the pump casing 7 and the motor 3 are pulled out, the discharge pipe supporter 100 can continue to support the discharge pipe P2. Although not shown, a pressure tank (not shown) connected to the discharge pipe P2 may be arranged between the two pump devices 1. In this case, the legs 302a of the support member 302 may be arranged so as to straddle the pressure tank.

FIG. 7 is a diagram showing a pump casing 7 and a motor 3 pulled out in the side pull-out direction. As shown in FIG. 7, the water supply device 300 may be arranged adjacent to the wall WL depending on the installation environment of the water supply device 300. In this case, since the wall WL is arranged in the vicinity of the motor 3 at the position on the rear side of the motor 3, it is difficult to pull out the pump casing 7 and the motor 3 in the back pull-out direction.

In the embodiment shown in FIG. 7, the pump casing 7 is connected to a suction flange 200 having a disk shape extending parallel to the axis CL direction of the rotating shaft 10. The casing contact surface 200b of the suction flange 200 and the end wall 19 of the suction casing 16 extend in parallel with each other, and the suction flange 200 has only the casing contact surface 200b in contact with the end wall 19 of the suction casing 16. , Connected to the suction casing 16. Therefore, the movement of the pump casing 7 in the side pull-out direction is not hindered by the suction flange 200, and the pump casing 7 and the motor 3 can be pulled out in the side pull-out direction.

Further, by arranging the discharge pipe supporter 100 between the leg portion 302a of the support member 302 and the pump casing 7, the movement of the pump casing 7 in the side pull-out direction is not hindered by the discharge pipe supporter 100, and the discharge pipe is not hindered. Since the supporter 100 can support the discharge pipe P2, it is possible to prevent the discharge pipe P2 from being deformed or damaged.

As shown in FIG. 7, the control panel 301 is arranged on the gantry 302b so that its direction can be changed. Therefore, when the water supply device 300 is arranged adjacent to the wall WL, the control panel 301 is preferably arranged so that the operation panel 312 faces the same direction as the side pull-out direction. With such an arrangement, the operator can operate the operation panel 312 at a position lateral to the motor 3, and can pull out the pump casing 7 and the motor 3 in the side pull-out direction.

Hereinafter, the structures of the suction casing 16, the intermediate casing 20, and the discharge casing 18 will be described with reference to the drawings. In the present embodiment, the suction casing 16, the intermediate casing 20, and the discharge casing 18 are made of resin. Examples of resins include polyamide (PA), polypropylene (PP), or polyphenylene sulfide (PPS). The resin suction casing 16, the intermediate casing 20, and the discharge casing 18 are lighter than the metal pump casing, and the overall material cost and processing cost of the pump casing 7 can be reduced. Since the high pressure of the liquid moving inside the pump casing 7 acts on the pump casing 7, the pump casing 7 must have a structure having high pressure resistance.

In order to increase the pressure resistance of the pump casing 7, it is conceivable to increase the wall thickness of the suction casing 16, the intermediate casing 20, and the discharge casing 18. However, if the wall thickness of the resin is increased, it takes a long time in the manufacturing process until the melted resin is completely solidified. Further, in this case, the resin may have a depression called a “sink”. In the worst case, cavities may be formed inside the resin. Further, the resin may have a phenomenon peculiar to the resin called creep deformation. Creep deformation is a phenomenon in which a resin is plastically deformed as a result of high pressure continuing to act on the resin for a long period of time. “Sinks” and / or cavities can promote creep deformation. Creep deformation of the resin can damage the pump casing or allow liquid to leak out of the pump casing.

The pump casing 7 according to the present embodiment has a structure for solving the above-mentioned problems. In the present embodiment, the suction casing 16, the intermediate casing 20, and the discharge casing 18 all have basically the same structure. Therefore, the drawings of the intermediate casing 20 of the pump casing 7 will be referred to below. I will explain.

FIG. 8 is an enlarged view of the intermediate casing 20. As shown in FIG. 8, the resin intermediate casing 20 has an annular inner peripheral wall (inner side wall or first peripheral wall) 21 having a size capable of accommodating the impeller 6B inside, and outside the inner peripheral wall 21. The inner peripheral wall 21 and the outer peripheral wall 22 are arranged between the arranged annular outer peripheral wall (outer wall or the second peripheral wall) 22 and the inner peripheral wall 21 and the outer peripheral wall 22 and reinforce the inner peripheral wall 21. It is provided with a reinforcing member 23 fixed to the casing. The inner peripheral wall 21, the outer peripheral wall 22, and the reinforcing member 23 are made of resin and are integrally molded members.

The thickness of the inner peripheral wall 21 and the thickness of the outer peripheral wall 22 are determined as necessary in terms of the strength of the pump casing 7. In one embodiment, the thickness of the inner peripheral wall 21 and the thickness of the outer peripheral wall 22 may be the same. In this case, from the viewpoint of the strength of the pump casing 7, the thickness of the portion of the pump casing 7 to be the thickest is determined, and the thickness of the inner peripheral wall 21 and the thickness of the inner peripheral wall 21 are determined according to the determined thickness of the portion of the pump casing 7. Make the thickness of the outer peripheral wall 22 uniform. As a result, resin molding of the pump casing 7 can be easily performed. In other embodiments, the thickness of the inner peripheral wall 21 and the thickness of the outer peripheral wall 22 may be different. In this case, the thickness of the portion of the pump casing 7 that requires strength can be increased, and the thickness of the portion of the pump casing 7 that does not require strength can be reduced. As a result, the material cost of the pump casing 7 can be suppressed.

In one embodiment, at least one of the suction casing 16, the discharge casing 18, and the intermediate casing 20 has a resin inner peripheral wall, a resin outer peripheral wall arranged so as to surround the inner peripheral wall, and an inner peripheral wall. A resin reinforcing member arranged between the and the outer peripheral wall may be provided.

FIG. 9 is a view seen from the direction of line A in FIG. FIG. 10 is a view seen from the direction of line B of FIG. In FIGS. 9 and 10, the impeller 6B and the partition member 50 (described later) are not shown. The outer peripheral wall 22 is arranged so as to surround the inner peripheral wall 21. The inner peripheral wall 21 and the outer peripheral wall 22 are arranged concentrically with the rotating shaft 10 to form a double wall.

As shown in FIGS. 9 and 10, the reinforcing member 23 includes a radial rib 23a extending toward the radial outer side of the inner peripheral wall 21 (that is, the radial inner side of the outer peripheral wall 22) and the inner peripheral wall 21 (and the outer peripheral wall). 22) is provided with an axial rib 23b extending in the axial direction. Here, the axial direction of the inner peripheral wall 21 (and the outer peripheral wall 22) means a direction parallel to the axis CL direction of the rotating shaft 10.

In the embodiment shown in FIGS. 9 and 10, the number of radial ribs 23a is 16, but the number of radial ribs 23a is not limited to this embodiment. The number of axial ribs 23b is 16, but the number of axial ribs 23b is not limited to this embodiment. In one embodiment, the intermediate casing 20 may include only the axial ribs 23b and, if desired, the radial ribs 23a.

In the present embodiment, each of the four axial ribs 23b has a through hole 20a having a size that allows the above-mentioned fastening member 8 (see FIG. 1) to penetrate. The through hole 20a extends parallel to the axial rib 23b.

The radial ribs 23a and the axial ribs 23b are alternately arranged at equal intervals along the circumferential direction of the inner peripheral wall 21 (and the outer peripheral wall 22). Axial ribs 23b (or radial ribs 23a) are arranged between the radial ribs 23a (or axial ribs 23b) adjacent to each other. More specifically, as shown in FIG. 8, the radial ribs 23a are arranged between both ends 26 and 27 of the axial ribs 23b. In the present embodiment, the radial rib 23a and the axial rib 23b are integrally molded members.

The high pressure of the liquid boosted by the impeller 6B acts on the inner peripheral wall 21 surrounding the impeller 6B, and stress is generated on the inner peripheral wall 21. In the present embodiment, the intermediate casing 20 has a double wall structure and includes a reinforcing member 23. Therefore, the intermediate casing 20 can improve its pressure resistance and can withstand the pressure of the liquid acting on the inside of the intermediate casing 20.

According to the present embodiment, the intermediate casing 20 can sufficiently withstand the pressure of the liquid without increasing its wall thickness. Therefore, the wall thickness of the component of the intermediate casing 20 can be made relatively thin, and the formation of cavities due to the thickening of the resin wall thickness does not occur. Further, in the present embodiment, since the outer casing (see, for example, Patent Document 2) that covers the components of the pump casing can be eliminated, the material cost and the processing cost can be suppressed.

As shown in FIGS. 9 and 10, the intermediate casing 20 includes a partition wall 24 extending inward in the radial direction from the inner peripheral surface 21a of the inner peripheral wall 21 toward the rotation axis 10. The partition wall 24 is a member that separates the pump chamber in the front stage and the pump chamber in the rear stage. The partition wall 24 has an annular shape, and an inner peripheral surface 24a is formed in the center thereof.

The thickness of the partition wall 24 is determined as necessary in terms of the strength of the pump casing 7. In one embodiment, the thickness of the partition wall 24 may be the same as the thickness of the inner peripheral wall 21 and the thickness of the outer peripheral wall 22. In this case, from the viewpoint of the strength of the pump casing 7, the thickness of the portion of the pump casing 7 to be the thickest is determined, and the thickness of the partition wall 24 is determined according to the thickness of the determined portion of the pump casing 7. Make the thickness of the inner peripheral wall 21 and the thickness of the outer peripheral wall 22 uniform. As a result, resin molding of the pump casing 7 can be easily performed. In other embodiments, the thickness of the bulkhead 24, the thickness of the inner peripheral wall 21, and the thickness of the outer peripheral wall 22 may be different. In this case, the thickness of the portion of the pump casing 7 that requires strength can be increased, and the thickness of the portion of the pump casing 7 that does not require strength can be reduced. As a result, the material cost of the pump casing 7 can be suppressed.

The intermediate casing 20 shown in FIG. 8 and the suction casing 16 adjacent to the intermediate casing 20 have a structure of being fitted to each other. Similarly, the intermediate casing 20 shown in FIG. 8 and the discharge casing 18 adjacent to the intermediate casing 20 have a structure in which they are fitted to each other.

Hereinafter, the fitting structure of the pump casing 7 will be described with reference to FIG. FIG. 11 is a cross-sectional view showing a fitting structure of the pump casing 7. The inner peripheral wall 21 has an annular end surface 21b located on the suction casing 16 side and an annular end surface 21c located on the discharge casing 18 side. The end surface 21b on the suction casing 16 side is formed with an annular protrusion 28 extending in a direction (horizontal direction) away from the end surface 21b, and the end surface 21c on the discharge casing 18 side is in a direction away from the end surface 21c (horizontal direction). An annular protrusion 29 extending in the horizontal direction) is formed. The annular protrusion 29 has an annular inclined surface 29a formed inside the annular projection 29.

Each of the suction casing 16 and the discharge casing 18 has a double-wall structure similar to that of the intermediate casing 20. More specifically, the suction casing 16 includes an annular inner peripheral wall 31 having a size capable of accommodating the impeller 6 inside, an annular outer peripheral wall 32 arranged outside the inner peripheral wall 31, and an inner peripheral wall 31. It is provided with a reinforcing member 33 arranged between the outer peripheral wall 32 and the outer peripheral wall 32 and fixed to the inner peripheral wall 31 and the outer peripheral wall 32 so as to reinforce the inner peripheral wall 31. The reinforcing member 33 includes an axial rib 33b having a structure similar to that of the axial rib 23b described above. Although not shown, the reinforcing member 33 may include radial ribs having the same structure as the radial ribs 23a described above.

The discharge casing 18 includes an annular inner peripheral wall 36 having a size capable of accommodating the impeller 6 inside, an annular outer peripheral wall 37 arranged outside the inner peripheral wall 36, and the inner peripheral wall 36 and the outer peripheral wall 37. It is provided with a reinforcing member 38 arranged between them and fixed to the inner peripheral wall 36 and the outer peripheral wall 37 so as to reinforce the inner peripheral wall 36. The reinforcing member 38 includes a radial rib 38a (see FIG. 1) having a structure similar to that of the radial rib 23a described above, and an axial rib 38b having a structure similar to that of the axial rib 23b described above.

As shown in FIG. 11, the inner peripheral wall 31 of the suction casing 16 has an annular end surface 31a located on the intermediate casing 20 side. An annular protrusion 34 extending in a direction away from the end surface 31a is formed on the end surface 31a. The annular protrusion 28 of the intermediate casing 20 and the annular protrusion 34 of the suction casing 16 are fitted to each other. Therefore, when the pump casing 7 is assembled, the annular protrusion 28 is in close contact with the end face 31a, and the annular protrusion 34 is in close contact with the end face 21b.

The annular projection 34 has an annular inclined surface 34a formed inside the annular projection 34, and when the annular projection 34 is in close contact with the end surface 21b, the annular projection 34 is in contact with the annular inclined surface 34a, the end surface 21b, and the annular projection 28. Seal space 35 is formed. An annular sealing member (for example, an O-ring) 40 is arranged in the sealing space 35, and the sealing member 40 seals a gap between the suction casing 16 and the intermediate casing 20.

The inner peripheral wall 36 of the discharge casing 18 has an annular end surface 36a located on the intermediate casing 20 side. An annular protrusion 39 extending in a direction away from the end surface 36a is formed on the end surface 36a. The annular protrusion 29 of the intermediate casing 20 and the annular protrusion 39 of the discharge casing 18 are fitted to each other. Therefore, when the pump casing 7 is assembled, the annular protrusion 39 is in close contact with the end face 21c, and the annular protrusion 29 is in close contact with the end face 36a.

When the annular projection 29 is in close contact with the end surface 36a, an annular seal space 55 is formed between the annular inclined surface 29a, the end surface 36a, and the annular projection 39. An annular seal member (for example, an O-ring) 56 is arranged in the seal space 55, and the seal member 56 seals a gap between the discharge casing 18 and the intermediate casing 20.

Such a fitting structure of the pump casing 7 may have a structure in which an intermediate casing different from the intermediate casing 20 is arranged between the suction casing 16 (and / or the discharge casing 18) and the intermediate casing 20. The same is true.

As shown in FIG. 11, the partition wall 24 is arranged between one end surface 21b and the other end surface 21c of the inner peripheral wall 21 in the axial direction of the inner peripheral wall 21. In one embodiment, the partition wall 24 may be arranged at the central portion of the inner peripheral wall 21 in the axis CL direction. The radial ribs 23a are arranged between the inner peripheral wall 21 and the outer peripheral wall 22 so as to be aligned with the partition wall 24. This straight line is a line segment extending in a direction perpendicular to the axis CL direction of the rotating shaft 10.

On the inner peripheral surface 21a of the inner peripheral wall 21 and the surface 24b of the partition wall 24 on the discharge casing 18 side, a plurality of velocities energy given to the liquid by the rotation of the impeller 6 are converted into pressure energy (in the present embodiment). , 7) The guide blades 45 are fixed. The plurality of guide blades 45 are made of resin and are integrally formed with the inner peripheral wall 21 and the partition wall 24. The guide blades 45 are provided not only in the intermediate casing 20 but also in the suction casing 16 and the discharge casing 18.

The plurality of guide blades 45 are arranged at equal intervals along the circumferential direction of the inner peripheral wall 21, and are located outside in the radial direction of the impeller 6. The plurality of guide blades 45 extend spirally, and each of the plurality of guide blades 45 has a curved shape. A guide flow path 47 through which a liquid passes is formed between the guide blades 45 adjacent to each other.

On the inner peripheral surface 21a of the inner peripheral wall 21 and the surface 24c on the suction casing 16 side of the partition wall 24, a plurality of (seven in this embodiment) for rectifying the liquid introduced into the impeller 6 of the next stage The return blade 46 is fixed. The return blades 46 are provided not only in the intermediate casing 20 but also in the discharge casing 18.

The plurality of return blades 46 are made of resin and are integrally formed with the inner peripheral wall 21 and the partition wall 24. The plurality of return blades 46 are arranged at equal intervals along the circumferential direction of the inner peripheral wall 21, and extend in a spiral shape. Each of the plurality of return blades 46 has a curved shape. A return flow path 48 through which a liquid passes is formed between the return blades 46 adjacent to each other. The guide blade 45 and the return blade 46 constitute a guide device.

FIG. 12 is a diagram showing a comparative example for explaining the effect of the intermediate casing 20 according to the present embodiment. FIG. 13 is a diagram for explaining the effect of the intermediate casing 20 according to the present embodiment. As shown in FIG. 12, when the impeller 600 rotates, the liquid is boosted by the impeller 600. The high pressure of the liquid acts on the radial outside of the impeller 600 and acts on the wall member 601 surrounding the impeller 600 (see arrow in FIG. 12).

The cross section of the wall member 601 has an L shape, and the rear end portion of the wall member 601 is a free end. As described above, since the distance from the front end portion of the wall member 601 to the rear end portion of the wall member 601 is long, the rigidity of the wall member 601 with respect to the pressure of the liquid is low. Therefore, when a high pressure of the liquid acts on the wall member 601, the amount of deformation of the wall member 601 becomes large, and a relatively large stress (first stress) is generated in the wall member 601.

As shown in FIG. 13, in the present embodiment, the partition wall 24 is arranged between both end faces 21b and 21c of the inner peripheral wall 21. With such an arrangement, the distance from the partition wall 24 to the end face 21c (and the end face 21b) is relatively short, so that the rigidity of the inner peripheral wall 21 is improved. Therefore, even if the high pressure Pa of the liquid acts on the inner peripheral wall 21, the amount of deformation of the inner peripheral wall 21 is small, and a large stress is not generated on the inner peripheral wall 21, which is larger than the first stress described with reference to FIG. A small stress (second stress) is generated.

Under the condition that the distance between the impeller 6 in the front stage and the impeller 6 in the rear stage (so-called interstage pitch) is the same, as shown in FIGS. 12 and 13, the inner peripheral wall 21 and the inner peripheral wall 21 according to the present embodiment and The length L1 of the pressure receiving portion of the outer peripheral wall 22 is shorter than the length L2 of the pressure receiving portion of the wall member 601. Therefore, the intermediate casing 20 can sufficiently withstand the pressure Pa of the liquid.

The liquid is stepwise boosted in a multi-stage pump chamber and transferred to the outside. Since the pressure of the liquid generated in the pump chamber of the subsequent stage is higher than the pressure of the liquid generated in the pump chamber of the front stage, there is a differential pressure (so-called interstage difference) between the pump chamber of the front stage and the pump chamber of the rear stage. Pressure) is generated. Therefore, as shown in FIG. 13, a liquid pressure Pb acting as an interstage differential pressure acts on the surface 24b of the partition wall 24 on the discharge casing 18 side toward the surface 24c of the partition wall 24 on the suction casing 16 side. According to the present embodiment, the guide device (that is, the guide blade 45 and the return blade 46) and the partition wall 24 are integrally molded members, and the guide device functions as a reinforcing material (rib). Therefore, the intermediate casing 20 can have high rigidity and can withstand the pressure Pb of the liquid acting on the surface 24b of the partition wall 24 on the discharge casing 18 side.

Since the intermediate casing 20 according to the present embodiment has high rigidity, it can sufficiently withstand the high pressure of the liquid and can suppress the occurrence of creep deformation. Further, since the intermediate casing 20 is made of resin, the weight of the pump device 1 as a whole can be reduced, and the cost of the pump device 1 as a whole can be reduced.

FIG. 14 is a diagram showing a partition member 50. As shown in FIGS. 1 and 14, the pump 2 further includes a partition member 50 that separates the guide blade 45 and the return blade 46. The partition member 50 is an annular plate member and is arranged adjacent to the return blade 46. The partition member 50 is made of resin and is a separate member from the intermediate casing 20. In one embodiment, the partition member 50 may be made of a metal such as stainless steel.

As shown in FIG. 14, a plurality of liquid inflow portions (fluid inflow portions) 51 are formed on the outer peripheral surface 50a of the partition member 50. The number of liquid inflow portions 51 corresponds to the number of guide flow paths 47 (and return flow paths 48). In the present embodiment, since the number of each of the guide flow path 47 and the return flow path 48 is 7, seven liquid inflow portions 51 are formed. The plurality of liquid inflow portions 51 are arranged at equal intervals along the circumferential direction of the partition member 50.

Each of the plurality of liquid inflow portions 51 is a notch extending from the outer peripheral surface 50a of the partition member 50 toward the inner peripheral surface 50b of the partition member 50. The shape of the liquid inflow portion 51 is not limited to this embodiment as long as the liquid can pass through the partition member 50.

The liquid boosted by the impeller 6 in the previous stage passes through the guide flow path 47 and passes through the plurality of liquid inflow portions 51. After that, the liquid is guided to the next stage impeller 6 through the return flow path 48.

FIG. 15 is an enlarged view of the seal structure shown in FIG. FIG. 16 is a diagram showing another embodiment of the seal structure. In the embodiment shown in FIG. 15, the seal member 40 is arranged in the seal space 35 formed between the annular inclined surface 34a, the end surface 21b, and the annular protrusion 28. In other words, the pump casing 7 has an annular triangular seal groove formed between the suction casing (first casing) 16 and the intermediate casing (second casing) 20, and the seal member 40 has the annular triangular seal groove. It is mounted in the seal groove.

In one embodiment, as shown in FIG. 16, the annular projection 34 does not have an annular inclined surface 34a, instead the inner peripheral wall 21 has an annular seal groove 234 formed on its end surface 21b. You may. In other words, the pump casing 7 has an annular parallel seal groove formed between the suction casing (first casing) 16 and the intermediate casing (second casing) 20, and the seal member 40 has the annular parallel seal groove. It is mounted in the seal groove.

In the embodiment shown in FIG. 16, the annular seal groove 234 faces the annular protrusion 34, and a seal space 235 is formed between the annular seal groove 234 and the annular protrusion 34. The seal member 40 is arranged in this seal space 235.

In the embodiment shown in FIG. 15, the seal space 35 has a triangular shape whose size gradually decreases toward the outer side in the radial direction of the pump casing 7. In the embodiment shown in FIG. 15, the triangular seal space 35 is formed by the cross section of the inner peripheral wall 31 and the cross section of the inner peripheral wall 21. Due to such a shape, the pressure of the liquid boosted by the impeller 6 acts on the inner peripheral wall 21 and the inner peripheral wall 31, and when the inner peripheral wall 21 and the inner peripheral wall 31 are deformed toward the outer side in the radial direction of the pump casing 7, the inner peripheral wall 21 and the inner peripheral wall 31 are deformed. The size of the seal space 35 may change. As a result, the amount of crushing of the seal member 40 changes, and the seal member 40 may not be able to properly prevent the leakage of liquid.

In the embodiment shown in FIG. 16, the seal member 40 arranged in the seal space 235 is compressed between the annular protrusion 34 (that is, the end surface of the suction casing 16) and the seal compression surface 234a of the annular seal groove 234. There is. The annular protrusion 34 and the seal compression surface 234a extend parallel to each other along the radial direction of the pump casing 7.

As described above, the seal space 235 has a quadrangular shape whose size does not change toward the outer side in the radial direction of the pump casing 7. In the embodiment shown in FIG. 16, the rectangular seal space 235 is formed by the cross section of the inner peripheral wall 31 and the cross section of the inner peripheral wall 21. Due to such a shape, the pressure of the liquid boosted by the impeller 6 acts on the inner peripheral wall 21 and the inner peripheral wall 31, and the inner peripheral wall 21 and the inner peripheral wall 31 are deformed toward the outside in the radial direction of the pump casing 7. However, since the size of the seal space 235 does not change, the amount of crushing of the seal member 40 does not change, and the seal member 40 can appropriately prevent the liquid from leaking.

By providing the pump casing 7 with the annular parallel seal groove in this way, the seal member 40 can stably exhibit its sealing performance even if the pump casing 7 is deformed. The annular triangular seal groove can exert an effect such as reduction of manufacturing cost. Therefore, an annular triangular seal groove and / or an annular parallel seal groove can be adopted based on various conditions for designing the pump device 1.

Although not shown, an annular triangular seal groove (see FIG. 15) may be formed between the intermediate casing 20 and the discharge casing 18, or an annular parallel seal groove (see FIG. 16) may be formed.
In one embodiment, an annular triangular seal groove (or an annular parallel seal groove) may be formed between the suction casing 16 and the intermediate casing 20, and an annular parallel seal groove (or an annular parallel seal groove) may be formed between the intermediate casing 20 and the discharge casing 18. Alternatively, an annular triangular seal groove) may be formed.

In the above-described embodiment, the pump 2 as the horizontal axis multi-stage pump has been described, but the pump 2 may be a horizontal axis single-stage pump. FIG. 17 is a diagram showing another embodiment of the pump device 1. Since the configuration of the present embodiment not particularly described is the same as that of the above-described embodiment, the duplicated description will be omitted.

As shown in FIG. 17, the pump 2 includes a rotating shaft 10, an impeller 6 fixed to the rotating shaft 10, a suction flange 200 having a suction port 15, and a pump casing 7 having a discharge port 17. ing. The combination of the suction flange 200 and the pump casing 7 is the casing assembly 250.

The pump casing 7 includes a resin inner peripheral wall 91 having a size capable of accommodating the impeller 6 inside, a resin outer peripheral wall 92 arranged so as to surround the inner peripheral wall 91, and an inner peripheral wall 91 and an outer peripheral wall. A resin reinforcing member (radial rib 93a and axial rib 93b) 93 arranged between the 92 and the 92 is provided. The inner peripheral wall 91, the outer peripheral wall 92, and the reinforcing member 93 are integrally molded members.

Also in the embodiment shown in FIG. 17, the fastening member 8 penetrates the suction flange 200 and the pump casing 7 and is inserted into the insertion hole 13a formed in the motor casing 13. The pump device 1 is assembled by tightening the fastening member 8.

FIG. 18 is a diagram showing still another embodiment of the pump device. In the above-described embodiment, the pump device 1 includes a motor casing 13 connected to the pump casing 7, and a rotating shaft 10 to which the impeller 6 and the rotor 11 are fixed. In the embodiment shown in FIG. 18, the pump device 1 includes a rotating shaft 10 to which the impeller 6 is fixed, and a drive shaft 320 to which the rotor 11 is fixed. The rotating shaft 10 and the drive shaft 320 are connected to each other via a coupling (shaft joint) 330.

As shown in FIG. 18, the pump casing 7 and the motor casing 13 are arranged apart from each other and are arranged on both sides of the coupling 330. With such a configuration, the pump casing 7 can be pulled out in the side pull-out direction while the motor 3 is supported by the motor supporter 205 and the suction flange 200 is supported by the flange supporter 215. More specifically, the operator releases the connection between the rotating shaft 10 and the drive shaft 320 via the coupling 330, and removes the fastening member 8. As a result, the pump casing 7 is separated from the suction flange 200 and the motor 3, so that the operator can pull out the pump casing 7 in the side pull-out direction.

Also in the embodiment shown in FIG. 18, the fastening member 8 may be inserted into the insertion hole 13a formed in the motor casing 13, or the fastening member 8 may be inserted into the pump casing 7 (not shown). May be provided.

In the embodiment shown in FIG. 18, the pump device 1 including the pump 2 as the horizontal axis single-stage pump has been described, but such a pump device 1 may include the pump 2 as the horizontal axis multi-stage pump.

In the above-described embodiment, the pump device 1 is a horizontal-axis pump device in which the rotary shaft 10 (and the drive shaft 320) extends in the horizontal direction, but the configuration of the pump device 1 is not limited to the above-described embodiment. In one embodiment, the pump device 1 may be a vertical axis pump device (vertical axis single-stage pump device or vertical axis multi-stage pump device) in which the rotary shaft 10 (and the drive shaft 320) extends in the vertical direction.

Although the embodiments of the present invention have been described so far, the present invention is not limited to the above-described embodiments, and it goes without saying that the present invention may be implemented in various different forms within the scope of the technical idea.

1 Pump device (mechanical device)
2 Pump (rotary machine)
3 Motor (motor)
6A to 6C impeller 7 Pump casing 8 Fastening member 10 Rotating shaft 11 Rotor (rotor)
12 Stator (stator)
13 Motor casing 13a Insertion hole 15 Suction port 16 Suction casing 17 Discharge port 18 Discharge casing 19 End wall 19a Communication hole 20 Intermediate casing 20a Through hole 21 Inner peripheral wall 21a Inner peripheral surface 21b End surface 21c End surface 22 Outer wall 23 Reinforcing member 23a Radial direction Rib 23b Axial rib 24 Partition 24a Inner peripheral surface 24b Surface 24c Surface 26, 27 Both ends 28 Circular protrusion 29 Circular protrusion 31 Inner peripheral wall 31a End surface 32 Outer wall 33 Reinforcing member 33b Axial rib 34 Circular protrusion 34a Circular inclined surface 35 Seal Space 36 Inner peripheral wall 36a End surface 37 Outer wall 38 Reinforcing member 38a Radial rib 38b Axial rib 39 Circular projection 40 Sealing member 45 Guide blade 46 Return blade 47 Guide flow path 48 Return flow path 50 Partition member 50a Outer peripheral surface 50b Inner peripheral surface 51 Liquid inflow part 55 Seal space 56 Seal member 91 Inner peripheral wall 92 Outer wall 93 Reinforcing member 93a Radial rib 93b Axial rib 100 Discharge pipe supporter 200 Suction flange 200a Suction port side surface (first surface)
200b Casing contact surface (second surface)
201 Reinforcing rib 202 Seal member 203 Seal groove 210 Main body 211 Suction port 215 Flange supporter 215a Suction flange side part 215b Base side part 215c Connection part 216 Fastener 217 Fastener 218 Through hole 219 Screw hole 234 Circular seal groove 234a Seal compression Surface 235 Seal space 250 Casing assembly 300 Water supply device 301 Control panel 302 Support member 302a Leg 302b Stand 312 Operation panel 320 Drive shaft 330 Coupling B Base CL Axis line P1 Suction pipe P2 Discharge pipe WL Wall

Claims (10)

With an impeller
The rotating shaft to which the impeller is fixed and
A casing assembly for accommodating the impeller and
The casing assembly is
A suction flange having a suction port that can be connected to the suction pipe and having an annular shape extending perpendicular to the axial direction of the rotation axis, and a suction flange.
A pump device comprising a pump casing connected to the suction flange. The suction flange has a casing contact surface that is in contact with the pump casing and extends parallel to the end wall of the pump casing.
The pump device according to claim 1, wherein the suction flange is connected to the suction casing in a state where only the casing contact surface is in contact with the end wall of the pump casing. The casing assembly includes a flange supporter that supports the suction flange.
The pump device according to claim 1 or 2, wherein the suction flange has a screw hole into which a fastener can be inserted through a through hole formed in the flange supporter. The pump device
A stator and a rotor that rotate the rotating shaft,
A motor casing accommodating the stator and the rotor,
A fastening member for fastening the casing assembly and the motor casing is further provided.
The pump device according to any one of claims 1 to 3, wherein the fastening member extends through the casing assembly and is inserted into an insertion hole formed in the motor casing. The pump device according to any one of claims 1 to 4, wherein the suction flange is made of resin or metal. The pump casing has a discharge port that can be connected to a discharge pipe.
The pump device according to any one of claims 1 to 5, wherein the pump device includes a discharge pipe supporter that supports the discharge pipe. The pump device according to any one of claims 1 to 6.
It is equipped with a control panel equipped with an operation panel.
The operation panel is a water supply device arranged so as to face the same direction as the pull-out direction of the pump casing. The maintenance method for a pump device according to any one of claims 1 to 6.
With the suction pipe connected to the suction flange, the operation of the pump device was stopped.
A method in which the connection between the pump casing and the suction flange is released, and the pump casing is pulled out to the side of the suction flange. The method according to claim 8, wherein the step of pulling out the pump casing to the side of the suction flange is performed in a state where the suction flange is supported by a flange supporter that supports the suction flange. The step of pulling out the pump casing to the side of the suction flange is performed in a state where the discharge pipe is supported by a discharge pipe supporter that supports the discharge pipe connected to the discharge port of the pump casing. 8 or the method according to claim 9.

Images