JPH0631193Y2 - Submersible pump with convex strainer bottom plate - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial field of application] The present invention relates to a submersible pump for effectively sucking or excavating water bottom or sea bottom sediment.

[Conventional technology]

Conventionally, various forms of submersible pumps have been known as submersible pumps used for the above purpose.
There is a form shown in the figure.

In the figure, 1 is an impeller casing surrounding the impeller 2, and the casing 1 is provided with a earth and sand suction port 3 by opening the central portion of its bottom plate. Reference numeral 4 denotes a cylindrical strainer continuously provided in a lower portion of the impeller casing 1, and the cylindrical strainer 4 is connected to a lower portion of the tubular portion 5 and a tubular portion 5 whose upper end is coupled to the lower portion of the impeller casing 1. The bottom plate 6 is provided with a central opening 7. Also,
Reference numeral 8 is an output shaft of a rotary motor (not shown).
Extends below the bottom plate 6 through the earth and sand suction port 3 of the impeller casing 1 and the central opening 7 of the cylindrical strainer 4, and a stirring cutter 9 is fixed to the extended end thereof. Incidentally, 10 is a supporting leg for supporting the pump.

With this configuration, when the rotary motor is operated, the output shaft 8, the impeller 2, and the stirring cutter 9 rotate integrally, stirring the earth and sand located below the stirring cutter 9, and the stirring flow V ₁ is indicated by an arrow. As described above, it can be sucked into the impeller casing 1 through the through holes H ₁ and H ₂ provided in the tubular portion 5 and / or the bottom plate 6 of the tubular strainer 4, and then discharged to the outside using an appropriate earth and sand discharge pipe. be able to.

(C) Problems to be solved by the device However, in suction work of earth and sand, when the concentration of earth and sand is high, a strong suction force is required. However, in the conventional submersible pump, the bottom plate 6 is flat. Therefore, as shown by the arrow in FIG. 8, the stirring flow V ₁ flows into the inside of the cylindrical strainer 4 through the through hole H ₁ in a non-orthogonal state forming an acute angle with respect to the bottom plate 6. Large inflow resistance when passing through H ₁ ,
It was not possible to effectively suck dirt and the like into the impeller casing 1 through the cylindrical strainer 4.

An object of the present invention is to provide a submersible pump that can solve the above problems.

(D) Means for Solving the Problems The present invention is directed to a rotary motor built in a pump casing, an impeller casing connected to the lower part of the casing, and a cylindrical strainer with a bottom plate connected to the lower end of the impeller casing. And an output shaft of a rotary motor extending downward through a central opening provided in the bottom plate of the impeller casing and the cylindrical strainer, and an impeller and a stirring cutter fixed to the output shaft in the impeller casing and the bottom plate, respectively. In the submersible pump provided, the bottom plate of the cylindrical strainer is a perforated bottom plate having a large number of through holes, and the bottom plate has a lower outer peripheral edge side and a central opening side higher convex sectional shape. The present invention relates to a submersible pump having a convex strainer bottom plate.

(E) Embodiment Hereinafter, the present invention will be described in detail based on an embodiment shown in the accompanying drawings.

FIG. 1 shows the entire structure of the submersible pump according to the present invention. A is a pump casing having a rotary motor B built therein, and C is a pump portion connected to the lower portion of the pump casing B.

Further, FIG. 2 shows the internal structure of the pump portion C of the submersible pump according to one embodiment of the present invention.

As is apparent from the illustrated configuration, the submersible pump according to the present invention has a basic configuration substantially similar to that of the conventional pump described above. In this embodiment, the same configuration as the conventional pump is used. As a rule, the members are designated by the same reference numerals with 10 added.

Next, the configuration that characterizes the present invention will be described with reference to FIGS. 2 to 7.

That is, in FIG. 2, the cylindrical strainer 14 has a large number of through holes 21 in the bottom plate 16 thereof, and the stirring flow V generated under the bottom plate 16 can be sucked into the impeller casing 11 through the through holes 21. .

Further, the bottom plate 16 has the central opening 1 from the outer peripheral edge side 16a.
7, the bottom plate 16 having a convex cross section can be formed, and a smooth stirring flow can be formed as described below.

Next, the operation of the submersible pump having such a configuration will be described.

When the stirring cutter 19 is rotated, a stirring flow V composed of a mixture of earth and sand and water is formed as shown by the arrow in FIG.

That is, the inclined bottom plate 16 is provided from the central opening 13 to the outer peripheral side 16
Since it is inclined radially downward toward a, as shown in FIG. 2, the stirring flow V passes through the through holes 21 provided on the inner peripheral side of the bottom plate 16 and is substantially orthogonal to the inclined bottom plate 16. Can flow into the impeller casing 11 and the agitated flow V is transmitted through the through hole 2
By reducing the fluid resistance received when passing through 1, it is possible to strongly suction even high-concentration earth and sand into the impeller casing 11.

Further, in FIG. 2, the diameter of the central opening 17 of the bottom plate 16 is considerably larger than the diameter of the output shaft 18 and substantially equal to the diameter of the stirring cutter 19, so that the central opening 17 is an annular communication channel having a sufficient opening area. Can be formed, and the occurrence of cavitation at the same place can be effectively prevented.

However, the shape of the central opening 17 is not limited to that shown in FIG. 2, but as shown in FIG.
It may be slightly larger than the diameter of 8. However, it is desirable from the viewpoint of cavitation prevention that the diameter of the central opening 17 is set between the base end and the outer end of the plurality of stirring blades 19b fixed around the base 19a of the stirring cutter 19.

Further, the tubular portion 15 of the tubular strainer 14 may be perforated by providing a through hole 22 as shown in FIG. 3 instead of being non-perforated as shown in FIG.

In this case, the through hole 22 provided in the tubular portion 15 can be used as an opening for density adjustment.

That is, water can be further added to the sediment flow flowing into the impeller casing 11 through the through holes 22 to dilute the concentration of the sediment flow to the extent that the rotary motor B is not overloaded.

Further, FIGS. 4 to 7 show another embodiment of the present invention.

The embodiment shown in FIG. 4 has an annular flat plate 16 around the central opening 17.
The convex bottom plate 16 is formed by forming an annular inclined plate 16d which forms c and extends from the outer peripheral edge of the annular flat plate 16c toward the lower end edge of the cylindrical strainer 14.

In the embodiment shown in FIG. 5, an inverted truncated conical cylinder 16e whose lower end communicates with the central opening 17 is provided around the central opening 17, and the conical cylinder 16e extends from the upper outer peripheral edge toward the lower end edge of the cylindrical strainer 14. The convex bottom plate 16 is formed by providing the extending annular inclined plate 16f.

In the embodiment shown in FIG. 6, the opening 1 is formed around the central opening 17.
A truncated conical cylinder 16g having 7 as the upper end is provided.
The convex flat plate 16 is formed by connecting the outer peripheral edge of the lower end of g to the inner peripheral edge of an annular flat plate 16h that is connected to the lower end of the cylindrical portion 15 of the cylindrical strainer 14.

The embodiment of FIG. 7 is characterized in that the convex bottom plate 16 has a bowl-shaped curved cross section.

Also in the above embodiment (FIGS. 4 to 7), FIG.
Similar to the embodiment shown in FIG. 3, the agitated flow is passed through the through hole 21 in a state substantially orthogonal to the bottom plate 16 to allow the stirring flow to flow in the cylindrical strainer 1.
4 can flow into the impeller casing 11, and highly concentrated soil or the like can be efficiently sucked into the impeller casing 11.

The impeller casing 11 may have another shape such as a volute type, and may have a structure in which a strainer or the like is attached to the lower portion. Further, the design elements such as the shape of the stirring cutter 19 and the blade pitch can be arbitrarily changed, and the model having the optimum pumping characteristic for the processing target can be selected.

[Effect of device]

As described above, in the present invention, the bottom plate of the cylindrical strainer is provided with a hole, and the bottom plate has an upwardly convex cross-sectional shape in which the position of the central opening is higher than the outer peripheral edge of the bottom plate. Can flow in a substantially orthogonal state to the bottom plate, reducing the fluid resistance that the stirring flow receives when passing through the through holes, and even if it is highly concentrated earth and sand, it can be efficiently sucked into the impeller casing for dredging work. The efficiency of can be improved.

[Brief description of drawings]

FIG. 1 is an overall front view of a submersible pump according to the present invention, FIGS. 2 to 7 are explanatory views of the essential structure of the submersible pump, and FIG. 8 is an explanatory view of the essential parts of a conventional submersible pump. In the figure, V: stirring flow 11: impeller casing 12: impeller 13: earth and sand suction port 14: cylindrical strainer 15: cylindrical portion 16: bottom plate 17: central opening 18: output shaft 19: stirring cutter 21: through hole

Claims (1)

[Scope of utility model registration request] 1. A rotary motor (B) built in a pump casing (A), an impeller casing (11) connected to a lower portion of the casing (A), and a bottom plate connected to a lower end of the impeller casing (11). A cylindrical strainer (14) with (16), a rotary motor extending downward through a central opening (17) provided in the bottom plate (16) of the impeller casing (11) and the cylindrical strainer (14).
The output shaft (18) of (B) is provided with an impeller (12) and a stirring cutter (19) fixed to the output shaft (18) in the impeller casing (11) and the bottom plate (16), respectively. In the submersible pump, the bottom plate (16) of the cylindrical strainer (14) is a perforated bottom plate having a large number of through holes (21), and the bottom plate (16) is attached to the outer peripheral edge (1
A submersible pump having a convex strainer bottom plate, characterized in that it has an upwardly convex cross-sectional shape with a lower side on the 6a) side and a higher side on the central opening (17) side.