JPH0631195Y2 - Submersible pump with stirring flow control ring - 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, reference numeral 1 denotes an impeller casing surrounding the impeller 2, and the casing 1 has a bottom plate center portion opened to serve as a sediment suction port 3. 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 under 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, the suction can be sucked into the impeller casing 1 through the through holes S ₁ and S 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 a suitable earth and sand discharge pipe. be able to.

(C) Problems to be solved by the invention However, in such a submersible pump, as shown by the dotted line, a part of the agitated flow V ₁ again flows downward through the central opening 7 of the cylindrical strainer 4 together with the downward flow. To form a circulation flow, so that the stirring flow could not be effectively and smoothly sucked into the impeller casing 1, and a satisfactory suction efficiency could not be obtained.

An object of the present invention is to provide a submersible pump that can solve such 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 the 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, at least while providing a through hole in the bottom plate of the cylindrical strainer,
Connect the upper edge of the stirring flow control ring concentrically arranged around the central opening to the lower surface of the bottom plate, and further connect the lower end of the ring to the height of the cutter from the lower end of the stirring cutter by 4 /
Position the stirring cutter 5 to 1/2 upward to project the stirring cutter below the lower edge of the stirring flow control ring, and set the annular distance from the outer peripheral edge of the stirring blade of the stirring cutter to the inner peripheral edge of the ring. The present invention relates to a submersible pump including a stirring flow control ring, which has a width substantially equal to that of a stirring blade.

(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 in which a rotary motor B is incorporated, 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. The members are shown with the same reference numerals plus 10.

Next, the structure that characterizes the present invention will be described with reference to FIGS. 2 to 5.

That is, as shown in FIG. 2, the cylindrical strainer 14 is connected to the lower surface of the bottom plate 16 of the cylindrical strainer 14 by the upper edge of the agitation flow control ring 30 concentrically arranged around the central opening 17.

As a connecting method, in addition to welding, it is also possible to connect using bolts and nuts made of a non-rusting metal.

Further, the stirring flow control ring 30 has a lower end of the ring from the lower end of the stirring cutter 19 to 4/5 to 1 of the height h of the cutter.
The stirring cutter 19 is positioned at a position of 1/2 (2 / 3h in FIG. 2) so that the stirring cutter 19 projects below the lower edge of the stirring flow control ring 30.

Further, the annular distance D between the outer peripheral edge of the stirring blade 19b fixed around the base 19a of the stirring cutter 19 and the inner peripheral edge of the stirring flow control ring 30 is made substantially equal to the width H of the stirring blade 19b. .

The mounting position of the stirring flow control ring 30 is set as described above because the initial flow a of the stirring flow V is, as shown in FIG.
While not disturbed by the ring 30, the reversal flow b of the stirring flow V except for a part thereof is
It flows out radially without being further hindered, and then, effectively, the through holes 21 provided in the bottom plate 16 and the through holes 2 provided in the tubular portion 15.
This is for passing through 2 to be sucked into the impeller casing 11.

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 upward flow c moving upward from the lower center of the stirring cutter 19 and the downward flow d moving downward from the central opening 17 join to form the initial flow a of the stirring flow V, and the initial flow a is the radial direction. And is inclined downward (the inclination angle is determined by the twisting angle of the stirring blade 19a of the stirring cutter 19), and then while being formed into the reversal flow b, the suction is smoothly sucked into the impeller casing 11 through the through hole 21 of the bottom plate 16. It

As described above, the stirring flow control ring 30 allows almost all of the stirred earth and sand to smoothly flow into the impeller casing 11 through the through holes 21 provided in the bottom plate 16, thereby improving suction efficiency.

3 and 4 show another embodiment, which is characterized in that, in addition to the stirring flow control ring 30, the bottom plate 16 is further inclined from its outer peripheral edge toward the central opening 17. And

With such a configuration, it is possible to further increase the suction efficiency of the sand according to the concentration of the sand.

That is, FIG. 3 shows a bottom plate structure capable of efficiently sucking high-concentration earth and sand, and FIG. 4 shows a bottom plate structure for efficiently sucking low-concentration earth and sand.

Further, in the above embodiment, the diameter of the central opening 17 of the bottom plate 16 is, as shown in FIG. 2, between the root diameter and the tip diameter of the stirring blade 19b provided around the base 19a of the stirring cutter 19. Any value can be selected, and by such selection, the central opening 17 can form an annular communication channel having a sufficient opening area, and cavitation can be effectively prevented at the same place.

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.

Further, the stirring cutter 19 is not limited to the form shown in FIGS. 1 to 5, and for example, the stirring cutter 19 shown in FIGS. 6 and 7 can be used.

In FIG. 6, the stirring cutter 19 is a propeller, and in FIG. 7, the stirring cutter 19 is a flat plate-shaped stirring blade 19b having no twist angle on a cylindrical base 19a having the same diameter.
It is supposed to be configured by installing.

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 is not overloaded.

The impeller casing 11 may have another shape such as a volute type, and a strainer or the like may be 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 has a hole, and the stirring flow control link is connected to the lower surface of the bottom plate and around the central opening.
Once the sand on the seabed is suctioned upwards, then diffused radially in all directions, smoothly flowing into the cylindrical strainer through the through holes provided in the bottom plate and the cylindrical strainer,
Then, substantially all of the stirred earth and sand can be effectively flowed into the impeller casing through the earth and sand suction port to improve the suction efficiency.

[Brief description of drawings]

1 to 7 are structural explanatory views of a submersible pump according to the present invention, and FIG. 8 is a structural explanatory view of a conventional submersible pump. In the figure, 11: Impeller casing 12: Impeller 13: Sediment suction port 14: Cylindrical strainer 15: Cylindrical part 16: Bottom plate 17: Central opening 18: Output shaft 19: Stirring cutter 20: Support legs 21, 22: Through hole 30: Ring for stirring flow control

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, at least the bottom plate (16) of the tubular strainer (14) should have a through hole (2
1) is provided and the bottom plate (16) has a central opening (17) on the bottom surface.
Connect the upper edges of the agitation flow control ring (30) arranged concentrically around it, and further connect the lower end of the ring (30) to the height of the cutter (19) from the lower end of the agitation cutter (19). 4/5 of (h)
The stirring cutter (19) is positioned upward by 1/2 and the stirring flow control ring (30) is projected downward from the lower edge of the stirring flow control ring (30), and the stirring blade (19b) has the same outer peripheral edge of the stirring blade (19b). Ring (3
0) to the inner peripheral edge of the annular spacing (D), the width of the stirring blade (19b)
A submersible pump provided with a ring for stirring flow control, which is approximately equal to (H).