KR101598165B1 - Pit barrel pump and method for incorporating same - Google Patents

Abstract

The pit barrel type pump has suction swirl preventing means that does not cause miniaturization of pits and performance deterioration. The orbiting pump includes a pump suction port provided at a lower end portion for sucking the working fluid, an impeller attached to the rotating shaft adjacent to the suction port, and a guide disposed on the downstream side of the impeller to increase the working fluid, And a blade. A vortex prevention device was installed below the pump inlet. The outer diameter φd ₀ of the pump inlet and the vortex prevention device is made smaller than the maximum outer diameter φd ₃ of the guide blades so that the vortex prevention device can be taken out from the pit together with the ingot pump.

Description

PIT BARREL PUMP AND METHOD FOR INCORPORATING SAME "

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pit-barrel type pump housing a vertical axis pump in airtight pits and a method of mounting the same.

An example of a conventional pit barrel type pump is disclosed in Patent Document 1. [ In the pump disclosed in this publication, a suction port is formed on the upper side surface of a bottomed tubular pit barrel in which a ceiling portion is opened. Then, the mouth pump is suspended from the upper opening of the pit barrel. A flange is provided at the discharge pipe portion of the orbiting pump, and the inside of the pit barrel is kept airtight by this flange closing the opening of the pit barrel.

In the pit barrel pump constructed as described above, the fluid sucked from the inlet port of the pit barrel descends between the inner wall surface of the pit and the outer peripheral surface of the orbiting pump suspended in the pit, and flows from the outer periphery of the pump inlet port, Lt; / RTI > The fluid, which is changed in the direction of flow approximately 180 degrees at the pump inlet, is sucked up vertically (upward) by the rotational force of the pump impeller and discharged to the discharge pipe via the impeller and the diffuser.

 However, it is an important problem to suppress the generation of vibration and noise due to underwater swirling in the orbiting pump used in the pit barrel type pump. In order to solve this problem, Patent Document 2 to Patent Document 4 disclose that anti-rotation means is provided at the inlet of the orbiting pump.

That is, in the entry / exit pump described in Patent Document 2, the suction whirlpool prevention member located at the lower end of the pump is mounted to prevent suction whirl. The suction swirl preventing member has an annular upper frame portion, a plurality of support portions extending vertically downward from the upper frame portion, a lower frame portion provided at the lower end of the support portion, And a baffle plate extending from the support portion of the suction bell toward an axial center of the suction bell.

Further, in the orbiting pump described in Patent Document 3, the sub-channel forming body forming the sub-channel between the outer periphery of the suction section and the suction section having the suction port provided in the water channel is substantially concentric . In addition, in the entry / exit pump of Patent Document 4, a rectifying plate device having a rectifying plate for rectifying the water flowing into the suction bell mouth is provided on the bottom surface of the suction water tank below (below) the tip of the suction bell mouth , And a suction bell mouth is fixed to this rectifying plate device.

Japanese Patent Application Laid-Open No. 7-324700 Japanese Patent Application Laid-Open No. 2010-190184 Japanese Patent Laid-Open No. 2002-155898 Japanese Unexamined Patent Application Publication No. 2002-147383

Nakano Tomoki, "Brine Recirculation Pump for Seawater Desalination Unit", Turbomachinery Association 91th Seminar - New Technology Trend Pamphlet of Pumps, March 24, 2010,

In the pit-barrel type pump described in Patent Document 1, the generation of vibration / noise due to the resonance phenomenon caused by the interference between the inlet / outlet pump and the influent water or the matching of the number of revolutions of the main shaft and the natural frequency of the inlet / A projection is provided on the wall surface of the pit barrel and an arm abutting the projection is provided on the pump so that the vibration of the pumping water pipe of the pump is suppressed by the bending reaction force of the arm. However, in the pump disclosed in Patent Document 1, there is no consideration for preventing the suction vortex generated in the flow that is drawn down from the pump suction pipe by descending the inside of the pit barrel.

On the other hand, the intake vortex prevention means of the orbiting pump described in Patent Documents 2 to 4 is considered effective means for preventing the generation of suction vortices. However, unlike a pit-barrel type pump, the pumps disclosed in these publications are not pit-filled pits in an airtight pit, but a pit structure in which a sufficient low-liquid portion is formed in a number of rows and a transverse direction. As a result, the direction in which the liquid is introduced into the orbiting pump does not vary by about 180 degrees in the pump suction portion, and in most cases, it is only a flow change of about 90 degrees.

Therefore, there is no limitation on the size in the width direction of the anti-swirl means installed in the pump suction port, and it is possible to form the swirl prevention means with a sufficient width. That is, in the chopping pump described in these publications, it is not considered sufficiently to store the anti-swirl means in a limited space such as a pit. In the pit barrel type pump, it is also desired to reduce the size of the pit, and it is also necessary to prevent the generation of unstable or less efficient flow due to the miniaturization of the pit.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems in the prior art, and an object thereof is to provide a suction-vortex prevention device that does not cause miniaturization of a pit barrel and performance deterioration. Another object of the present invention is to realize a suction swirl preventing device which is compact in the pit barrel and has sufficient maintenance property in the pit barrel type pump.

According to a first aspect of the present invention, there is provided a pit-barrel-type pump including a barrel-shaped pit suspended from a mouth-hole pump, the pump including a pump inlet provided at a lower end of the barrel- And a diffuser disposed on a downstream side of the impeller and adapted to increase a working fluid to which a swirl component is imparted by the impeller, wherein a swirler is provided on the lower side of the pump inlet, Wherein the pump inlet and the vortex prevention device have an outer diameter that is smaller than a maximum outer diameter of the diffuser so that the vortex prevention device And the swirl generation preventing device comprises a base member, a peripheral member provided on the outer peripheral side of the base member, It has a plurality of ribs of the plate-like are arranged at intervals in the direction, which is integral with the said vortex prevention apparatus and the pump inlet, by fixing the plurality of the ribs to the pump inlet.

In this aspect, it is preferable that the base member of the vortex prevention device is formed by combining a flat plate formed in a flat plate or taper shape with a member formed in a circular plate or a cone shape.

In the above aspect, the pit may be made of reinforced plastic, and the pit may be formed into a cylindrical shape having a bottom, and a bottom surface in contact with the pit of the vortex prevention device may be formed into a curved surface whose outer peripheral portion is curved upward.

According to another aspect of the present invention for achieving the above object, there is provided a pneumatic tire comprising a concave portion for accommodating a barrel-shaped pit formed with a flange at an upper end thereof, Wherein the flange of the inlet pump is brought into contact with the flange of the inlet pump to accommodate the inlet pump in the pit and the inlet pump is placed in a state of being in a state of being embedded in the pit.

According to the present invention, in the pit barrel type pump which is used to suspend the orbiting pump in the pit barrel, the pivot preventive means having a diameter smaller than the pump outer diameter is fixed to the pump suction port, so that miniaturization and performance deterioration of the pit barrel Suction swirl preventing means is obtained. In addition, it is possible to realize the suction whirling preventing means with the miniaturization of the foot barrel and the maintenance property.

1 is a longitudinal sectional view of an embodiment of a pit-barrel type pump according to the present invention.
2 is a cross-sectional view of the pit barrel-type pump shown in Fig.
3 is a longitudinal sectional view of another embodiment of a pit-barrel type pump according to the present invention.
4 is a cross-sectional view of the pit barrel-type pump shown in Fig.
5 is a longitudinal sectional view of another embodiment of a pit-barrel type pump according to the present invention.
6 is a cross-sectional view of the pit barrel-type pump shown in Fig.
7 is a longitudinal sectional view of still another embodiment of a pit-barrel type pump according to the present invention.
8 is a longitudinal sectional view of another embodiment of a pit-barrel type pump according to the present invention.

Hereinafter, some embodiments of the pete barrel type pump according to the present invention will be described with reference to the drawings.

Example 1

Fig. 1 is a vertical sectional view of an embodiment of a pit-barrel type pump 50 according to the present invention. The present pit-barrel type pump 50 is used as a brine circulation pump in, for example, a multi-stage flash type seawater desalination plant. The inside of the barrel-shaped pit 1 is filled with fluid. An example of this seawater desalination pump is described in Non-Patent Document 1 and has a size of 900 mm, a design point flow rate of 137.2 m 3 / min, a head lift of 21.5 m, and a required power of 670 kW.

In the pit barrel-type pump 50 shown in this embodiment, a pit 1 for supplying a working liquid (water or seawater) to the pit 1 is provided at the upper side of a barrel- And the suction port 9 is formed at a substantially right angle to the axis of the pit 1. [ The pit 1 is made of stainless steel or other highly resistant metal or reinforced plastic such as GFRP mixed with FRP or glass fiber in consideration of seawater desalination application and the like to secure corrosion resistance and pressure resistance strength .

That is, since the pit 1 becomes hermetic at the time of operation of the pump 50, it has a shape conforming to the pressure vessel. Therefore, the bottom portion of the pit 1 has a shape bulging downward like a mirror plate. Further, the upper end portion of the pit 1 is often provided on the ground surface or below. The pit (1) is buried in the ground, and its surroundings are embedded with concrete.

In the pit 1, the orbiting pump 8 is accommodated. The mouth pump 8 has a discharge pipe 12 in which a curved tube portion 12b is formed at an upper portion of a vertically extending rectilinear portion 12a. Although not shown, the curved tube portion 12b , And a pipe extending in the horizontal direction is connected. A flange 12c is attached to the lower portion of the bending portion 12b of the discharge pipe 12 and is bolted to the flange 1a provided at the upper end of the pit 1. [ Thereby, the orbiting pump 8 is hermetically suspended in the pit 1.

The pump suction port 2 located at the lower end of the orbiting pump 8 has a bell mouth shape that forms a reduced flow path. An impeller casing 6a and a diffuser casing 7a are provided in order above the suction port 2 and the diffuser casing 7a is connected to the straight portion 12a of the discharge pipe 12 .

An upper portion of the rotary shaft 5 is connected to an upper bearing 14 provided on the outer side of the bending portion 12b of the discharge pipe 12, As shown in Fig. Between the bending portion 12b and the upper bearing 14, a shaft sealing device 13 is attached. The shaft sealing device 13 seals the leakage of the working fluid of the orbiting pump 8 to the outside. The upper end of the rotary shaft 5 is connected to a prime mover (not shown).

A diagonal flow impeller 6 provided with a plurality of blades at intervals in the circumferential direction is attached to the lower end of the rotary shaft 5 and is fixed to the rotary shaft 5 with a nut 5a. A diffuser 7 is disposed on the rear side of the impeller 6 and a lower bearing 15 is held on an inner peripheral portion of the boss side of the diffuser 7. The lower bearing (15) rotatably supports the rotary shaft (5) together with the upper bearing (14).

Here, as a feature of the present invention, the vortex prevention device 4 is provided in the suction port 2 formed in a bell mouth shape. The vortex prevention device 4 of the orbiting pump 8 shown in Fig. 1 includes a conical member 4a (base member) having a truncated conical shape and a plurality of conical members 8), and plate-like ribs 3 arranged at substantially equal intervals in the circumferential direction. The rib 3 is provided to form a flow path to the suction port 2 and to hold the cone shaped member 4a in the suction port 2. [ The rib 3 and the intake port 2 and the rib 3 and the cone member 4a are welded or bolted together, respectively.

The operation and the like of the pit-barrel type pump 50 thus constructed will be described below. The fluid sucked as the flow Fa from the suction port 9 of the pit 1 positioned at the upper portion of the barrel-shaped pit 1 in the pit barrel-type pump 50 flows into the straight portion 12a and the flow Fb flowing back to the peripheral portion of the inlet port 12a of the pump 8 from the inlet port 9 of the pit 1 to the inlet port 2 of the pump 8, And flows downward in the vertical direction Fc and Fd.

Flows Fe and Ff led to the inlet port 2 of the orifice pump 8 located below the pit 1 are formed. The flow that has reached the inlet port 2 of the bell mouth shape forming the reduced flow path is guided vertically upward by the rotation of the impeller 6 and flows through the impeller 6 and then the diffuser 7 into the discharge port 2, Flow Fj, and is discharged to the outside of the pit barrel-type pump 50.

The impeller 6 is driven by a prime mover (not shown) connected to the main shaft 5. Then, energy is imparted to the water, which is the working fluid sucked from the inlet 2 of the orbiting pump 8, by the rotation of the impeller 6 to raise the fluid. The diffuser 7 is a stop flow path, and rectifies the circumferential turning component of the flow imparted to the fluid by the impeller 6 in the axial direction to restore the pressure.

In order to suppress the occurrence of underwater vortexes generated from the lowermost portion of the pit 1 located below the suction port 2 of the pump 8 toward the suction port 2 of the pump 8, The vortex prevention device 4 is provided. In the present embodiment, a cone-type vortex prevention device 4 is attached in place of the vortex prevention plate.

However, in the case of the brine circulating pump, the pressure of the fluid at the inlet 9 of the pit 1 is lower than the atmospheric pressure. In addition, the depth of the pit 1 tends to become shallower in order to reduce the cost of civil engineering construction and production of the pit 1. Therefore, the pump press-in pressure in the vicinity of the suction port 2 of the pump 8 is low and is used under the condition that cavitation occurring in the water swirl or the impeller is likely to occur, as compared with a general pump having a free surface in contact with the atmosphere. Thus, the vortex prevention device 4 provided at the suction port 2 of the pump 8 prevents the occurrence of underwater vortexes and prevents the flow of the fluid flowing from the upper portion of the pit 1 from being interrupted, To the impeller (6) of the pump (8).

As the material of the barrel-shaped pit 1, reinforced plastic represented by GFRP mixed with stainless steel or other metal, FRP or glass fiber is used. In this embodiment, the pits 1 are made of reinforced plastic. In this case, it is difficult to attach the cone-shaped vortex prevention device 4 for preventing the occurrence of the vortex to the pit 1 or to integrally form the pit 1 on the pit 1. Thus, by inserting the vortex prevention device 4 with the rib 3 below the suction port 2 of the mouth-and-wheel pump 8, the suction port 2 and the vortex prevention device 4 are integrated have. In this way, it is possible to suspend the mouth-ring type pump 8 provided with the vortex prevention device 4 from above in the pit 1.

Conventionally, a swirl prevention plate or a cone-shaped swirl prevention device for preventing the occurrence of swirls has been attached to the side of the pit 1 below the suction port 2 of the suspended pump 8. According to the present embodiment, the cone-shaped member 4a for preventing the formation of the spiral is provided on the lower side of the suction port 2 of the pump 8 suspended from the upper portion of the pit 1, So that it is integrated with the suction port 2. The outermost diameter φd ₀ of the suction port 2 is set to be equal to the outermost diameter φd of the diffuser 7 so as not to interfere with the flow of the fluid from above the pit 2, ₃ < / RTI >

2 shows a swirl prevention device 4 integrated with the inlet 2 of the orbiting pump 8 and the ribs 3 in a transverse sectional view. Figure 2 is a view along line 10 of Figure 1. The cone-shaped vortex prevention device 4 is disposed concentrically with the pump suction port 2. Since the cone-shaped vortex generator 4 is provided below the suction port 2 of the pump 8, it is possible to suppress a sudden increase in flow speed locally generated at the suction port 2 of the pump 8. [ As a result, occurrence of underwater eddy can be prevented. When the overhang amount of the rotary shaft 5 of the multi-stage input shaft pump 8 is increased by using the cone-type eddy current generation preventing device 4, the rotation shaft 5 of the pump 8 is rotated, Shaped member 4a of the vortex prevention device 4 and rotatably supports the shaft end of the rotary shaft 5 by the bearing held by the cone member 4a, the amount of overhang is reduced .

According to the present embodiment, there is no need to attach a vortex prevention device on the bottom side of the barrel-shaped pit, and it is possible to design with priority to make the pit, thereby reducing the manufacturing cost of the pit. Conventionally, when a pit is made of a metal material, the vortex prevention device can be attached to the pit bottom by welding, so that the shape can be changed, but the pit preparation and maintenance are not good. Further, when the pits are made of reinforced plastic or the like, the shape change such as the additional processing of the pits themselves causes difficulty due to the change in strength, and the manufacturing cost is increased. In the present embodiment, however, It is very easy to make and economical.

According to the present embodiment, since the vortex prevention device 4 is disposed between the pit 1 and the suction port 2 of the pump 8, the cavitation generated during the operation in the partial flow rate range of the pump It is possible to prevent the accompanying impeller inlet backflow from damaging the pit 1. Even if the spiral prevention device 4 is damaged, the spiral prevention device 4 can be taken out at the same time as the pump 8 is pulled up by pulling up the suspended pump 8, The maintenance of the damaged portion of the apparatus can be facilitated.

In addition, even when it is necessary to change the shape of the vortex prevention device 4, the vortex prevention device 4 can be easily taken out. Therefore, as compared with the case where the vortex prevention device is fixedly installed on the bottom surface of the pit, Handling becomes easy. Further, according to the present embodiment, when the pump suspended from the pit is updated, the apparatus can be designed without considering the shape of the bottom of the pit. Therefore, the existing pit 1 can be used So that the time and cost for updating the pump can be suppressed.

Example 2

Another embodiment of the pit barrel type pump according to the present invention will be described with reference to Figs. 3 and 4. Fig. Fig. 3 is a longitudinal sectional view of the pit-barrel type pump 50, and Fig. 4 is a transverse sectional view along the sectional line 10 of Fig. The present embodiment is different from the above embodiment in that the swirl prevention plate 11 combined with a cross is attached to a circular flat plate (base member) 4c instead of the cone type swirl prevention device, ). Since the underwater vortex occurs due to the pressure drop at the turning center of the swirling flow, the swirling flow at the vicinity of the inlet port 2 of the pump 8 is suppressed by providing the anti-rotation plate 11 shown in Fig. do. Thus, the occurrence of underwater eddy is prevented. The anti-rotation plate 11 combines four plates having a height h and a length L / 2 in a cross shape. Further, each of the anti-rotation plates 11 is formed in a tapered shape in the height direction so that the flow can be smoothly sucked into the impeller 6.

Also in this embodiment, as in the above-described embodiment, it is possible to design a pit bottom portion prioritizing creation of the pit barrel type pump. In addition, damage to the pit bottom portion can be prevented, and the maintenance and shape change of the vortex prevention device can be facilitated. Further, the existing pits can be easily used at the time of updating the pump.

Example 3

Another embodiment of the pit barrel type pump according to the present invention will be described with reference to Figs. 5 and 6. Fig. Fig. 5 is a longitudinal sectional view of the pit-barrel type pump 50, and Fig. 6 is a transverse sectional view along the sectional line 10 of Fig. In the present embodiment, the structure is such that the anti-rotation plate 11b for further suppressing the swirling flow is added to the cone member 4a of the vortex prevention device 4 of the embodiment shown in Fig. Otherwise, it is the same as the embodiment shown in Fig. When the swivel preventing plate 11b is combined with the height h, the thickness t, and the cone member 4a, the length in the radial direction is L. [ By adopting such a shape, it is possible to suppress a sudden increase in flow rate locally generated at the pump inlet. Moreover, it is possible to suppress the swirling flow which is likely to occur at the axial center of the suction port 2, and the effect of further preventing the occurrence of underwater spirals can be obtained.

According to the present embodiment, as in the case of the embodiment shown in Fig. 1, it is possible to design the pit bottom portion prioritizing creation. In addition, damage to the pit bottom portion can be prevented, and the maintenance and shape change of the vortex prevention device can be facilitated. Further, the existing pit 1 can be easily used at the time of updating the pump.

Example 4

Another embodiment of the pit-barrel type pump 50 according to the present invention will be described with reference to Fig. 7 is a longitudinal sectional view of the pit-barrel type pump 50. Fig. In this embodiment, the shape of the pit 1a is different from the embodiment shown in Fig. Conventionally, in consideration of the pressure resistance of the pit 1, the bottom surface 1b of the pit 1 is bulged outward like a rigid plate of a pressure vessel. However, when the pressure resistance is ensured by other means, ) Shape. That is, when the thickness of the pit is large, the stress applied to the pit is small. By doing so, the making of the pit and the making of the pit area are improved.

Since the bottom surface of the pit 1a is formed into a cylindrical shape with the bottom of the flat plate, corners are formed at the lower corner of the pit 1a, and congestion of the flow may occur. In the present embodiment, the bottom outer circumferential portion 4g of the cone member 4f constituting the vortex prevention device 4 has a curved shape that is curved upward, because these are factors of generation of the suction vortex. Further, the outer diameter φd and _v of the cone-like members (4f), the outer diameter of the large diameter (大徑) than φd ₀ of the suction port (2b) of the pump (8). Otherwise, it is the same as the embodiment shown in Fig.

According to the present embodiment, the shape of the bottom of the cone member 4a shown in Fig. 1 has a curvature, and the fluid flowing down from the upper portion of the pit 1a can be smoothly guided to the suction port 2b of the pump 8 have. The outermost portion of the suction port 2b of the pump 8 also has a curved surface upward so that the flow from the upper portion of the pit 1a to the suction port 2b of the pump 8 becomes more smooth. It is possible to control the flow smoothly to be directed to the suction port 2b of the pump 8 irrespective of the shape of the bottom portion of the pit, thereby preventing occurrence of underwater spiral. Further, since the flow of the air flowing into the suction port 2b from the upper portion of the pit 1a can be controlled, the loss caused by the suction portion of the pump 8 can be reduced.

Example 5

Another embodiment of the pit-barrel type pump 50 according to the present invention will be described with reference to Fig. 8 is a longitudinal sectional view of the pit-barrel type pump 50. Fig. The present embodiment differs from the embodiment shown in Fig. 7 only in the shape of the inlet 2d of the orbiting pump 8. In the embodiment of Fig. 7, the outer peripheral side of the suction port 2a is bent upward, and the flow Fe and Ff are smoothly guided to the suction port 2a. The concave portion 2c formed on the outer peripheral side of the suction port 2d is covered with the member 2f in order to guide the flow Fe and Ff smoothly to the suction port 2d in this embodiment. As a result, the outer peripheral portion of the suction port 2d has a substantially cylindrical shape with an outer diameter of φd ₅ , and the constricted portion disappears.

The fluid introduced from the upper side of the pit 1a passes through the outer periphery of the diffuser 7 (outer diameter? D ₃ portion) when the fluid flows downward from the upper portion of the pit 1a toward the inlet port 2d of the pump 8, The flow becomes an axial flow. A space formed between the inner periphery of the pump 8, the outer circumferential portion and the foot (1a) of the gradually increasing geochimyeon the maximum diameter portion of the diffuser (7), from a minimum diameter φd ₅ parts of the inlet opening (2) of the pump again It changes into a reduced euro. Then, a very small flow passage area is formed at the end of the suction port 2 of the pump 8. If the fluid flows through the flow path that repeats such expansion and contraction, the flow loss increases.

In order to solve this problem, the change in the cross-sectional area of the flow path inside the pit 1a is reduced, the maximum diameter? D ₀ of the suction port 2d of the pump 8 is extended upward, Thereby reducing the loss of the euro. According to the present embodiment, it is possible to reduce the loss occurring inside the pit 1a and to prevent the deterioration of the fluid efficiency of the pump 8. In addition, the occurrence of eddies can be prevented.

In the present embodiment, the structure of reducing the loss due to expansion and contraction of the flow path between the lower portion of the flange of the diffuser 7 and the upper portion of the suction port 2d of the pump 8 is reduced. When the maximum diameter of the suction port 2 is made equal to or smaller than the maximum diameter of the diffuser 7, the same effect as described above can be obtained.

As described in the above embodiments, since the anti-rotation device is integrally provided at the inlet of the pump and the maximum diameter of the pump is set to the maximum diameter of the diffuser portion, the flow space formed between the outer periphery of the pump and the inner periphery of the pit It is not necessary to change the inner diameter of the pit according to the anti-rotation device. That is, if the pump specification is determined, the specification of the pit can be determined, and the pit can be downsized.

In the above embodiment, the pit is made of reinforced plastic. However, as described above, if the pit is made of any material such as stainless steel or other metal, GFRP mixed with FRP or glass fiber is excellent in corrosion resistance, The invention is applicable. Further, in the case of surface treatment or the like, even if the corrosion resistance is not so much, in the case of using in an environment in which corrosion resistance is not required, other materials may be used, and the present invention can be applied.

1, 1a: feet
1b and 1d:
2, 2a, 2b, 2d: (pump) inlet
2c:
2f:
3: rib
4: Vortex prevention device
4a, 4f: cone member
4c: disc member
4g: outer periphery
5:
6: Impeller
7: Diffuser
8:
9: (foot) inlet
10: Cross-sectional position
11, 11b: anti-rotation plate
50: Pete barrel type pump
d ₀ : Outlet diameter
d ₃ : Guide blade outer diameter
d ₅ : Suction minimum diameter
d _v : Vortex prevention device Outer diameter
Fa ~ Fj: Flow

Claims (5)

A pit barrel-type pump comprising a barrel-shaped pit suspended from a mouth-piece pump,
Wherein the inlet pump includes a bell mouth pump inlet formed at a lower end thereof for sucking working fluid,
An impeller attached to the rotating shaft adjacent to the suction port from above,
And a diffuser disposed on the downstream side of the impeller and for increasing a working fluid to which the swirl component is applied by the impeller,
A spiral prevention device is installed on the lower side of the pump suction port and at the pump suction port,
The outer diameter of the pump inlet and the vortex prevention device is made smaller than the maximum outer diameter of the diffuser so that the vortex prevention device can be taken out from the pit together with the inlet /
The vortex prevention device has a base member and a plurality of plate-like ribs arranged at equal intervals in the circumferential direction on the outer peripheral side of the base member,
Wherein the swirl prevention device and the pump suction port are integrated by fixing the plurality of ribs to the pump suction port,
Wherein the pit is formed into a cylindrical shape having a bottom, and a bottom surface in contact with the pit of the vortex prevention device is formed into a curved surface whose outer peripheral portion is curved upward. The method according to claim 1,
Wherein the base member of the vortex prevention device is formed by combining a flat plate formed in a flat plate or tapered shape with a member formed in a disk or a cone shape. 3. The method according to claim 1 or 2,
Wherein said pit is made of reinforced plastic. delete A concave portion for accommodating a barrel-shaped pit having a flange formed at an upper end thereof is formed on the ground surface, a barrel-shaped pit is held in the concave portion, a flange formed on the inlet-axis pump is brought into contact with the flange of the pit, Wherein said inlet / outlet pump is accommodated in a state where said inlet / outlet pump is housed in a pit, and said inlet / outlet pump is the inlet / outlet pump according to claim 1 or 2.

Images