JP5585831B2 - Submersible pump strainer - Google Patents

Description

  The present invention relates to a strainer in a submerged pump used when sucking and discharging (supply / drainage) a target liquid (target water) having a large amount of impurities such as a factory drain pit and a construction site.

As is well known, a submersible pump is usually provided with a filter having a large number of small suction holes in the vicinity of the suction port in order to avoid suction of foreign substances in the target water. However, there are many cases where submersible pumps are installed outdoors, and the suction holes of the filter are blocked at once by flexible, large surface area contaminants such as flying plastic packaging bags (so-called plastic bags) and fallen leaves. It often happens that the pump cannot pump.
In particular, in submersible pumps installed in the drainage pits of factories that operate continuously day and night, if these measures are not taken, the drainage will stop and hinder continuous operation. We must respond by monitoring and calling the time system.

  As a means for solving this problem, an attempt to delay the time to complete blockage by enclosing the entire outer periphery of the pump with a strainer to increase the suction surface area is known (for example, Patent Documents). 1). In this technology, when the entire pump is submerged, there is an effect of delaying the blockage to some extent, but when the water level is low, the actual water contact surface area of the strainer is reduced, and a strainer is provided only around the pump inlet. There will be no big difference from the normal one.

  Moreover, what equips the inside of a strainer with the crushing mechanism of a foreign material by another idea is known (for example, refer patent document 2). However, such a device has a complicated structure and only increases the manufacturing cost, and it has little effect to prevent a flexible material such as dead leaves from adsorbing to the strainer surface. The amount increases, the running cost increases, and there is a problem in terms of maintenance.

JP-A-6-249183 (FIG. 1) JP 7-332293 A (summary)

  An object of the present invention is to provide a strainer structure capable of preventing the suction port of the submersible pump from being blocked for a long time by flexible and large-sized impurities such as fallen leaves and resin packaging bags.

  That is, the present invention secures one end of a supple hollow tube having a number of through holes in the tube wall to a hole provided in the cover plate attached so as to surround the water absorption part of the pump. A large number of the hollow tubes project along the outer periphery, and the other end of the hollow tube is sealed, and is in a state where it can move freely without being fixed. It is a strainer structure.

  Preferably, the hollow tube is formed by braiding resin monofilaments and the crossing points of the monofilaments are not joined, and the covering plate is surrounded by the pump in the middle. The hollow plate is attached to the cover plate so as to protrude radially from the cover plate, and the cover plate is composed of a plurality of plates. This is a case where one or more hollow tubes are attached, and the attached plate has a structure that can be attached to and detached from the strainer structure, and a floating tool is attached to each hollow tube.

  The octopus foot strainer structure of the present invention is a hole provided in a cover plate in which a plurality of flexible hollow tubes having a large number of through holes in a tube wall are attached so that one end portion surrounds a water absorption portion of a pump. Is attached to the cover plate, and is used in a form in which a large number of hollow tubes protrude into the target liquid, and the other end of the hollow tube (i.e., Since the hollow tube is flexible without being fixed, the hollow tube can swing in the target liquid. Since a large number of hollow tubes are attached, the filter area is increased, and the three-dimensional uneven structure by the projection of the hollow tube into the target liquid of the hollow tube and the countermeasure water of the hollow tube. The swaying movement in the filter prevents dust and large-sized contaminants such as fallen leaves and resin packaging bags from adhering to the filter surface, and the adsorbed contaminants can be easily removed from the filter surface. Thus, it is possible to prevent suction failure (clogging) caused by adhesion of a contaminated portion having a large area over a long period of time.

  Furthermore, in the present invention, the hollow tube is a hollow tube in which resin monofilaments are braided so that the strands (monofilaments) are not joined together, thereby further enhancing the flexibility of the hollow tube, pump vibration and flow Thus, the hollow tube can be further swayed, so that the self-cleaning action of the surface of the hollow tube can be exerted to a high degree, and the above-mentioned contaminants can be separated without clogging for a long time.

  In the present invention, preferably, the cover plate is present so as to surround the periphery with the pump in the middle, and a hollow tube is attached to the cover plate so as to protrude radially from the cover plate. In such a case, the distance between the legs widens toward the tip of the hollow tube, and a large floating bag such as a plastic bag near the tip of the hollow tube located near the water surface at a distance from the support plate. An object is blocked, and it is possible to prevent the vicinity of the base of the hollow tube from being blocked with a plastic bag.

  In addition, a large floating substance blocked near the tip of the hollow tube becomes a barrier, and small floating dust can be blocked at the same time. Also, the present invention is preferably a case where the covering plate is composed of a plurality of plates, each plate has one or more hollow tubes attached, and each plate has a structure that can be attached and detached. By having such a structure, even if some of the hollow tubes are clogged, the clogged hollow tube can be easily removed and replaced with a new hollow tube. be able to.

  Furthermore, in the present invention, it is preferable that a floating tool is attached to a part of the hollow tube, so that it is present in a state where the waste liquid surface floats and is sunk in the bottom of the drain liquid. Therefore, it is possible to stably absorb liquid from an intermediate position of the drainage liquid, which is relatively free of impurities, and to exhibit the filter function without being clogged for a long time.

The typical perspective view which shows the position and direction of a typical submersible pump and the suction / discharge liquid (supply / drainage) with an arrow. (A) is a perspective view showing an example in which the hollow tube is straight (straight tube), (b) shows an example in which the hollow tube is bent, and the space between the braided wires is reduced The perspective view which shows having flexibility by being able to expand. (A) shows an example of a cover plate that surrounds the suction part of the submerged pump to which the hollow tube is attached. The cover plate can be divided and assembled so that the main body strainer of the submerged pump The perspective view which shows that it can cover with an empty tube, (b) shows an example of the coating plate which fixes a hollow tube, and shows that the plate which fixed the hollow tube by the arrow can be attached or detached easily. Perspective view. The perspective view which shows an example which attached the octopus foot-shaped strainer structure of this invention to the submerged pump.

Next, the present invention will be described with reference to the drawings.
FIG. 1 is an example of a typical submerged pump 1 according to the present invention. A liquid absorbing member having a large number of liquid absorbing holes 3, usually called a main body strainer 2, is attached to the water absorbing portion of the pump. The liquid is sucked from all directions at the bottom of the submerged pump as indicated by an arrow a, and discharged from an outlet 4 via a hose 5 as indicated by an arrow b. In the present invention, the octopus strainer structure of the present invention is mounted on or in place of the main body strainer.
The size of the submerged pump is not particularly limited, but an outer diameter of about 75 mmφ to 350 mmφ is common and suitable.

  2 (a) and 2 (b) are particularly preferred examples of the hollow tube constituting the octopus strainer structure of the present invention, in which resin monofilaments are braided and the intersections of the monofilaments are joined. FIG. 2 (a) shows a straight state (straight pipe), and FIG. 2 (b) shows an example of bending and showing flexibility. ing.

  The present invention aims to reduce the frequency of strainer clogging troubles. First, as a means for increasing the opening area in terms of shape, a flexible hollow tube having a large number of through holes in the tube wall, particularly a resin. It uses a structure in which monofilaments are braided and a large number of cage-shaped hollow tubes are provided in which the strands (monofilaments) are not joined. A cage shape in which such resin monofilaments are braided and the strands are not joined Hollow tubes are known as drainage pavement conduits. The present invention uses such a known conduit for a strainer structure which is a completely different application, and further improves the conduit.

  A flexible hollow tube having a number of through-holes in the tube wall is a water component that removes solid contaminants in the drainage from the through-hole into the hollow tube by introducing and sucking the hollow tube into the drainage. The contaminants in the drainage are those that have innumerable through holes in the tube wall so as not to enter the hollow tube. And that the hollow tube is flexible means that the hollow tube can be shaken by running water or vibration of the pump. Specifically, it is achieved by configuring the hollow tube with a flexible resin or fiber. Regarding the size of the through-hole, it is preferable that impurities do not pass through, and an appropriate size may be adopted depending on the wastewater to be treated. Regarding the number of through-holes, it is preferable to increase the number as much as possible within a range in which the hollow tube does not significantly reduce the strength. The thickness and length of the hollow tube are preferably in the same range as in the case of a cage-shaped hollow tube braided with resin monofilaments, which will be described later.

  The molding method and material of the cage-like hollow tube are not limited. The molding method may be an injection molding method, a braiding method, and the material may be steel wire, resin wire, bamboo chin, etc. However, the hollow tube is easy to fluctuate due to pump vibration and water flow, and it is possible to prevent the floating dust from adsorbing to a higher degree by self-cleaning, and the hollow tube itself or a part of itself is suspended. Considering that it is possible to suck from a liquid portion with a small amount of material, it is particularly preferable to braid a resin monofilament in a hollow shape and to have a braided structure that can freely slide without fixing the intersection of the monofilaments.

  As a suitable example of a structure that develops flexibility in the cage-shaped hollow tube, a configuration in which a cage (through hole) is formed by a repulsive force of a strand during braiding can be considered. Specifically, this is a case where the overlapping portions of the strands (overlapping portions of the monofilaments) are not joined. In such a case, since the joining is not joined, the braid pitch is increased on the bent outer periphery 7 and the opposite side. In the inner circumference 8 of the bend, the braiding pitch is reduced. This structural freedom is the source of the flexibility of the hollow tube and is the optimum structure of the hollow tube.

  The material of the element wire 9 is preferably lightweight, versatile, water-resistant, and corrosion-resistant mainly from the viewpoint of flexibility in use in water. As a suitable representative material, polypropylene ( Polyolefins represented by PP) and polyethylene (PE), polyesters represented by polyester terephthalate (PET) and polybutylene terephthalate (PBT), polyamides represented by nylon 6 and nylon 66, polyvinyl alcohol and ethylene -Monofilaments made of various resins such as vinyl alcohol resins such as vinyl alcohol copolymers are preferred, and polyester monofilaments are particularly suitable. And as thickness of a monofilament, the range of 0.5-2 mm in diameter is preferable at the point of productivity and filter performance.

  In the resin constituting the monofilament, a drug may be added for the purpose of preventing adhesion of aqueous organisms, and further, a colorant, various stabilizers, inorganic powder, and the like may be added. Furthermore, such a chemical | medical agent, a coloring agent, and inorganic powder may exist as a coating or a layer on the monofilament surface.

The form of the hollow tube depends on the size of the submerged pump because the usage method is combined with the submerged pump. At this time, the general size of the submersible pump is about 75φ to 350mmφ in outer dimensions. For reference, a hollow pipe of 12 to 48 spindles is used as a hollow tube suitable for a general submersible pump size. The monofilament is braided in an angle range of 45 degrees to 68 degrees with respect to the longitudinal direction of the tube, and the void area of the rhomboid cage surrounded by the monofilament is 0.5 to 8.0 mm ² , A cage-shaped hollow tube having a length of 30 to 200 cm and a thickness of 10 to 40 mm is preferable.

  The hollow tube forms a filter tube by sealing the tip on one side as a sealing portion 10 and does not particularly limit the sealing method, but a cap suitable for the outer diameter of the hollow tube A method of adhering and fixing to the tip of the hollow tube is simple and preferable.

  The octopus foot strainer structure according to the present invention attaches the end portion of the hollow tube that is not sealed to the hole provided in the cover plate that is attached so as to surround the water absorption portion of the submerged pump. The waste water sucked into the empty pipe passes through the hollow pipe and passes through the opposite side of the cover plate.

  A large number of hollow tubes are fixed to the covering plate, and when drainage is filtered, the hollow tubes protrude into the drainage liquid. Accordingly, the fixing portion that is structurally the root of the protruding portion, that is, the portion where the hollow tube is attached to the covering plate, is required to have a strength that can withstand water pressure.

  As a method for fixing the hollow tube to the cover plate, there are many methods such as fusion, adhesion, and nipple insertion. Although not particularly limited, a hole for fixing the end of the hollow tube is formed in the cover plate. In addition, a method of tightening the resin hollow female screw 11 adhered and fixed to the end of the hollow tube with a resin hollow male screw 12 passed from the opposite side of the hole in the cover plate and sandwiching the cover plate is convenient and preferable. It is.

  FIG. 3 (a) shows an example of a cover plate 12 constituting a octopus strainer structure. A hollow tube fixing hole 13 is formed in the cover plate, and the cover plate is fixed by screws A14. The structure can be divided and assembled into two parts, and by examining the size design, it is possible to cover the main body strainer without removing it, and further, it is fixed to the submersible pump with the screw B15. Is. Of course, the body strainer can be removed and replaced with the octopus strainer structure of the present invention.

  FIG. 3B also shows another example of the cover plate constituting the octopus strainer structure. Structurally, the covering plate is composed of a plurality of independent plates 16, and each plate can be easily attached and detached. Maintainability is improved by making individual plates easy to attach and detach. When the cover plate is made up of a plurality of removable plates, the plate is fixed to the plate fixing frame. As the fixing method, any structure can be considered as long as it can be attached and detached, such as hook-and-loop fasteners, hooks, slides, and screw fixings. However, a slide type that can be attached and detached by vertical movement as shown by an arrow e is reasonable and most preferable.

  The total number of hollow tubes attached to the covering plate is not particularly limited, and 2 to 100, particularly 4 to 50 are suitable. And as a raw material of a covering board, although a metal, resin, wood, concrete, etc. are mentioned, Preferably it is a board made from metal or resin. Further, the covering plate may be a flat flat surface, a curved surface, or a bent surface. Anyway, there is no problem as long as the structure completely covers the water absorption part of the pump. The size, shape, etc. of the cover plate can be freely determined according to the purpose of use, the installation location, the size of the pump to be used, and the like.

  FIG. 4 is a plan view showing a structure in which the hollow tube 6 shown in FIG. 2B is fixed to the cover plate 12 of the octopus strainer shown in FIG. 3A and attached to the typical submerged pump shown in FIG. 1 shows an example of the usage pattern of the present invention.

In the present invention, the most preferable structure is a structure in which a part of a plurality of supple hollow tubes having a large number of through-holes in the tube wall floats in the target liquid. Examples thereof include a structure in which a float is attached to the intermediate portion or the tip portion, preferably the tip portion. In such a structure, a material in which the resin and monofilament constituting the hollow tube are submerged in water, specifically, a resin having a density of 1 g / cm ³ or more or a high specific gravity is added, whereby the density is 1 g / cm 2. It is preferable that the resin composition is cm ³ or more because water can be absorbed from the middle of the drainage liquid.

  Even when the octopus foot-shaped strainer structure of the present invention is installed in an environment such as a drain pit with little liquid flow, these optimum structures are flexible, large-area floating contaminants such as young fallen leaves and resin packaging bags, etc. Can be prevented from being lost to the surface of the hollow tube, and the filter function can be prevented from being lost. Can be stably absorbed.

  Next, an Example demonstrates this invention.

Example As a cage-like hollow tube, 24 polyester (PET) monofilaments with a diameter of 1.2 mm are braided by a 24 spindle braider so that the wefts are joined at 62 degrees with respect to the longitudinal direction (the joining angle between the wefts is 124 degrees). An inner diameter of 20 mm and an outer diameter of 25 mm were prepared. The cage-shaped hollow tube is cut to a length of 30 cm, and a polyethylene foam having an outer diameter of 20 mm, a length of 10 mm, and an expansion ratio of 40 times is pushed into the tip as a float, and the inner diameter is 24 mm. A 10 mm cap was fitted and adhered and sealed. Then, a resin hollow female screw having an inner diameter of 24 mm was fitted and bonded to the other end to form a cage-like hollow tube (tip floating type) used in the present invention.

  Next, as a octopus strainer covering plate, a hexagonal frame made of SUS steel plate having a thickness of 1 mm, consisting of six side surfaces having a long side of 100 mm, a short side of 70 mm, and six terminal fixing holes is prepared. 36 cage hollow pipes are attached to all terminal fixing holes (36) via resin hollow male screws so that the covering plate is sandwiched, and a submersible pump with an outer diameter of 125 mm (rated drainage 50 liters) at the center. / Min) and the upper and lower open parts were sealed so as to cover and fix the main body strainer.

Comparative Example The same submersible pump as the one used in the example with an outer diameter of 125 mm (rated drainage amount of 50 liters / minute: no octopus strainer attached) was used as a comparative example.

Test method The water tank was filled with water 2 m long x 2 m wide x 1 m high (4000 liters) and placed on the bottom of the water tank (assuming a drainage pit with little flow). Furthermore, in each aquarium, 200 sheets of Japanese paper cut into a 10 cm square were allowed to settle for 24 hours and settled (corresponding to rotted leaves, 2 m ² in total, equivalent to a water tank surface area of 1/2), and a 10 cm square. 200 sheets of polyethylene foam sheet with a thickness of 1 mm and a foaming ratio of 40 times (corresponding to floating dust such as plastic bags and initial fallen leaves, 2 m ² in total, equivalent to 1/2 of the water tank surface area), and submersible pump The change in the amount of discharged water for 1 minute was measured every 10 minutes.

  The test results are summarized in Table 1.

  In Examples and Comparative Examples, even when the embodiment of the present invention is installed in a drainage pit with little liquid flow, the submersible pump sucks in by a large amount of foreign matter such as fallen leaves and resin packaging bags. It shows that the clogging of the mouth can be prevented for a long time.

  According to the present invention, in the submerged pump, it is more preferable that a large number of hollow tubes are combined in a form protruding from the main body strainer provided along the outer periphery of the bottom of the casing, and the suction surface area of the entire strainer is increased. Is a cage-like hollow tube formed by braiding resin monofilaments (in a state in which the strands are not joined), and has a flexibility to follow the flow and liquid level by partly floating For this reason, it is possible to prevent the suction port of the submerged pump from being blocked for a long period of time by flexible and large-sized impurities such as fallen leaves and resin packaging bags.

DESCRIPTION OF SYMBOLS 1 Submerged pump 2 Main body strainer 3 Liquid suction hole 4 Outlet 5 Hose 6 Hollow tube 7 Cage-shaped hollow tube 8 Bending outer periphery 9 Bending inner periphery 10 Sealing part 11 Fixing part 12 Cover plate which constitutes an octopus strainer 13 Terminal fixing hole 14 Screw A
15 Screw B
16 Fixed plate

Claims (4)

By fixing one end of a flexible hollow tube having a number of through holes in the tube wall to a hole provided in the cover plate attached so as to surround the water absorption part of the pump, A number of hollow tubes are provided in a protruding form, and the covering plate is composed of a plurality of plates. Each plate has one or more hollow tubes attached, and each plate has a structure that can be attached and detached. And the other end of this hollow pipe is sealed, and it is in the state which can move freely without being fixed, The pump foot-like strainer structure characterized by the above-mentioned. 2. The octopus-like strainer structure according to claim 1, wherein the hollow tube is a hollow tube formed by braiding resin monofilaments and the intersections of the monofilaments are not joined. The octopus foot according to claim 1 or 2, wherein a covering plate is present so as to surround the pump in the middle, and a hollow tube is attached to the covering plate so as to protrude radially from the covering plate. Strainer structure. The octopus-like strainer structure according to any one of claims 1 to 3 , wherein a float is attached to each hollow tube.

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