KR101846947B1 - Apparatus for removing deposits from straniner - Google Patents

Abstract

The present invention relates to an apparatus for removing foreign matters deposited on a filter net (25) of a strainer, comprising: a body (20) accommodating the filter net (25) on a flow path; an adsorption ring (30) displaceably accommodated in the filter net (25) and having a plurality of adsorption holes (31); and a cleaning unit (40) installed to induce displacement of the adsorption ring (30) and releasing foreign matters through the adsorption hole (31). Accordingly, productivity is improved in removing the foreign matters attached to the filter net by adding mobility to exclude a dead zone while occupying a relatively small space in the strainer and minimizing duct resistance.

Description

[0001] Apparatus for removing deposits from a straner [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a strainer of a fluid pipe, and more particularly, to a strainer removal device for discharging a foreign matter adhering to a filter network of a pipe stewerer to the outside.

Typically, a strainer is installed on a fluid pipe to filter foreign substances such as rust, debris and sand, and is classified into Y type, T type, and con type depending on the connection type. If it is a frozen form or if foreign matters which are deposited on the filter net are not cleaned frequently, it becomes a factor to increase the resistance of the fluid channel. For convenience of cleaning work, a self-cleaning method is preferred even if the filter is not drawn out.

Patent literature such as Korean Registered Utility Model No. 1996-0009122 (Prior Art 1) and Korean Patent Publication No. 2012-0114791 (Prior Art Document 2) are known as prior art documents which can be referred to in this connection.

In the prior art document 1, a "+" round bar is fixedly connected to the discharge pipe in the same direction as the discharge pipe in the same direction as the discharge pipe, And a drive handle which is extended to the drive shaft and rotates the discharge pipe. Thus, it is possible to completely remove the impurities during operation, thereby preventing cost loss and human loss.

Prior Art 2 is a strainer including a hollow rotary shaft having a plurality of suction pipes for sucking precipitated foreign matter, the hollow rotary shaft being vertically installed and rotating by a motor; Length adjusting means for moving the hollow rotary shaft in the vertical direction; And a suction valve for discharging foreign matter which can not be discharged to the suction pipe. Therefore, it is expected that the foreign matter is automatically removed without stopping the operation of the facility.

However, since the plurality of suction pipes shown in the prior art documents 1 and 2 are arranged in multiple layers at the predetermined positions of the strainer, it takes a considerable time to completely remove the deposited foreign substances as well as to increase the resistance of the fluid in the normal operation state.

1. Korean Utility Model Registration No. 1996-0009122 entitled "Automatic Cleaning Device for Wye-type Cylindrical Strainer" (Published on November 22, 1995). 2. Korean Patent Laid-Open Publication No. 2012-0114791 entitled "Self-cleaning Strainer" (published on October 17, 2012).

SUMMARY OF THE INVENTION It is an object of the present invention to overcome the above-mentioned problems of the prior art by providing a method and apparatus for removing foreign matter adhering to a filter net in a short period of time by occupying a relatively small space on a fluid channel, And to provide an apparatus for removing sediment of a strainer to be discharged.

In order to attain the above object, the present invention provides an apparatus for removing foreign matter deposited on a filter net of a strainer, comprising: a body for accommodating the filter net on a flow path; An adsorption ring accommodated in the filter net in a displaceable manner and having a plurality of adsorption holes; And a cleaning means installed to induce displacement of the adsorption ring and discharging foreign matter through the adsorption hole.

In a detailed configuration of the present invention, the adsorption ring has a hollow shaft connected to the center, and the end of the hollow shaft is exposed to the outside.

As a first embodiment of the present invention, the hollow shaft is watertightly mounted on a boss of the body via a mechanical seal.

As a second embodiment of the present invention, the hollow shaft is watertightly mounted on a support cap of a filter net via a mechanical seal.

As a modification of the present invention, the adsorption ring is further provided with an arcuate groove for retaining the filter net and the extended gap on the outer circumferential surface.

According to a further aspect of the present invention, the cleaning means includes a driver for causing the suction ring to move up and down in the axial direction through the hollow shaft.

In another modification of the present invention, the cleaning means is configured to additionally induce a rotational movement of the adsorption ring through the hollow shaft.

As described above, according to the present invention, there is an effect of enhancing the productivity of removing the foreign matter adhering to the filter net by adding mobility to occupy a relatively small space inside the strainer to minimize the duct resistance while excluding the dead zone.

1 is a block diagram generally illustrating an apparatus according to the present invention;
Figure 2 is a schematic diagram showing the main part of the device according to the invention
3 is a configuration diagram showing a main part according to a modification of the present invention
4 and 5 are schematic views showing the operating state of the apparatus according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The present invention proposes an apparatus for removing foreign substances deposited on a filter net 25 of a strainer. 1, a Y-type strainer connected to a pipe 10 by a flange is exemplified, but not always limited thereto. The filter net 25 forms an opening at the upper end and is integrally coupled to the support cap 26 at the lower end. The support cap 26 may be flanged or spirally coupled onto the body 20 described below.

According to the present invention, the body (20) has a structure in which the filter net (25) is accommodated on the flow path. The body 20 can be formed of a cast iron structure, a die casting structure of an aluminum alloy material, or a synthetic resin structure such as an engineering plastic. The filter net 25, which is mounted on the fluid channel of the body 20, is introduced with the fluid through the upper opening to accommodate the filtered foreign matter.

According to the present invention, the adsorption ring (30) having a plurality of adsorption holes (31) is accommodated in the inside of the filter net (25) so as to be displaceable. The adsorption ring 30 is formed to have a dimension close to the inner surface of the filter net 25 and a generally loose fit. Displacement of the adsorption ring 30 is an essential feature of an automatic cleaning function for removing foreign matter while varying the position (posture) on the filter net 25. The adsorption ring (30) has a plurality of adsorption holes (31) for adsorbing foreign matter on an outer circumferential surface opposed to the inside surface of the filter net (25).

As a detailed configuration of the present invention, the adsorption ring 30 has a hollow shaft 35 connected to the center, and the end of the hollow shaft 35 is exposed to the outside. In FIG. 1, since the suction ring 30 coupled to the lower end of the hollow shaft 35 is in contact with the support cap 26, an increase in the resistance of the fluid channel can be minimized as compared with the above-mentioned prior art. 2 (a) and 2 (b), the adsorption ring 30 has eight adsorption holes 31 along with an annular flow passage, and the adsorption ring 30 is connected to the hollow shaft 35, and the hollow shaft 35 communicates with all the suction holes 31 at the same time to form a discharge path for foreign matter. When the end of the hollow shaft 35 is exposed to the outside, driving force is externally applied to facilitate the displacement of the adsorption ring 30 and the automatic cleaning operation.

The hollow shaft 35 is watertightly held on the boss 21 of the body 20 via the mechanical seal 23. The hollow shaft 35 is made of a synthetic resin. 1 illustrates a state in which the end of the hollow shaft 35 is exposed using a boss 21 formed on the outer circumferential surface of the body 20. On the boss (21), a mechanical seal (23) is provided to enhance the water tightness of the hollow shaft (35). It is preferable that the protective cap 28 be mounted so as to be watertight while protecting the end portion of the hollow shaft 35 normally.

In the second embodiment of the present invention, the hollow shaft 35 is watertightly mounted on the support cap 26 of the filter net 25 via the mechanical seal 23. [ But the hollow shaft 35 may be exposed on the support cap 26 opposite to that shown in Fig. The boss 21 formed on the body 20 is unnecessary and the mechanical seal 23 is provided on the support cap 26. [ In this case, since the adsorption ring 30 is located at the opening of the filter net 25, the resistance of the fluid channel is somewhat increased as compared with the first embodiment.

As a modification of the present invention, the adsorption ring (30) further comprises an arcuate groove (32) for retaining the filter net (25) and the extended gap on the outer circumferential surface. 3, a blue arrow indicates a state in which the fluid flows backward after filtration and flows into the adsorption hole 31, and a red arrow indicates a state in which the fluid before filtration staying in the filter net 25 flows into the arc-shaped groove 32 . The enlarged clearance of the arc-shaped groove 32 can increase the filtering force of the red arrow passage, but becomes too large to lower the filtering force of the blue arrow passage. Thus, the size of the arc-shaped groove 32 is determined in accordance with the specification of the strainer and the physical properties of the fluid, and the arc-shaped groove 32 may be disposed at a position deviated from the attraction hole 31.

According to the present invention, the cleaning means (40) is installed to cause the displacement of the adsorption ring (30), and the foreign substance is discharged through the adsorption hole (31). The cleaning means 40 causes the displacement of the adsorption ring 30 through the hollow shaft 35 by means of a power source such as a pneumo-hydraulic cylinder that implements reciprocating motion, a motor that implements rotational motion, and the like. If there is no pump for backwashing of the filter net 25 on the pipe 10, a separate pump (not shown) is added to the cleaning means 40 to ensure the original activity of the foreign matter discharge through the adsorption holes 31 It is possible.

The cleaning means 40 includes a driver 48 for causing the suction ring 30 to move up and down in the axial direction through the hollow shaft 35. In the present invention, 4 and 5 illustrate a state in which the adsorption ring 30 is caused to move up and down. As shown in FIG. 4 and FIG. 5, foreign matters deposited on the filter net 25 can be adsorbed and discharged through the hollow shaft 35. In this case, a driver 48 having a motor as a drive source is mounted on the outer surface of the housing 41 having the flange 46 and a nut 42 and a helical shaft 45 are provided between the driver 48 and the hollow shaft 35. To transmit the driving force. The nut 42 and the spiral shaft 45 are preferably of a ball screw type, but are not limited thereto. The nut 42 is rotatably supported on the housing 41 and the drive 48 and the nut 42 are connected by a gear 43. The helical shaft 45 is hollow, . Thus, when the nut 42 is rotated by the rotation of the driver 48, the spiral shaft 45 and the hollow shaft 35 cause the up and down movement of the adsorption ring 30. [

At this time, the coupling 36 interposed between the hollow shaft 35 and the spiral shaft 45 can be constructed by applying a flange type having a watertightness or a known method similar thereto while transmitting the torque.

The auxiliary pipe 15 may be used when mounting the housing 41 of the cleaning means 40 to the boss 21 of the body 20. It is preferable that the auxiliary pipe 15 having the flange 46 at both ends is formed in a two-part hinge structure so as to be easy to attach and detach.

As a modification of the present invention, the actuator 48 may be a pneumo-hydraulic cylinder that directly pulls and pushes the hollow shaft 35. Of course, in this case, the spiral shaft 45 uses a general hollow shaft having no spiral.

In another modification of the present invention, the cleaning means 40 is configured to additionally induce a rotational movement of the adsorption ring 30 through the hollow shaft 35. This is implemented in such a manner that the spline shaft is engaged with the upper end of the spiral shaft 45 and the spline shaft is engaged with the pinion gear mounted on the separate driver 48. [ In addition to the up and down movement of the adsorption ring 30, it is advantageous to remove and remove the foreign substance deposited on the filter net 25 more quickly in case of causing rotational movement.

In operation. The protective cap 28 is detached from the body 20 shown in Fig. 1 and the helical shaft 45 of the cleaning means 40 is coupled to the hollow shaft 35 as shown in Fig. 4, 21 and the housing 41 and actuates the actuator 48 as shown in Fig. 5 to cause the adsorption ring 30 to rise. Accordingly, the foreign substances immersed in the filter net 25 or suspended therein are discharged to the outside through the suction holes 31, the hollow shaft 35, and the spiral shaft 45. If the foreign matter is not generated, the suction ring 30 is repeatedly moved up and down to return to the state of FIG. 4, the cleaning means 40 is removed, the auxiliary tube 15 is removed, and the protective cap 28 is mounted .

In the case where only the vertical movement of the hollow shaft 35 is implemented, a separate hose may be coupled to the end of the spiral shaft 45 to discharge foreign matter to a desired place. However, if the hose is long, It is preferable to add a joint (not shown) to transport the foreign matter.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention. It is therefore intended that such variations and modifications fall within the scope of the appended claims.

10: piping 15: auxiliary pipe
20: Body 21: Boss
23: mechanical seal 25:
26: support cap 28: protective cap
30: Adsorption ring 31: Adsorption ball
32: arc-shaped groove 34: arm
35: Hollow shaft 36: Coupling
40: cleaning means 41: housing
42: Nut 43: Tooth
45: spiral shaft 46: flange
48:

Claims (7)

An apparatus for removing foreign substances deposited on a filter net (25) of a Y-type strainer, comprising:
A body 20 for accommodating the filter net 25 on a flow path;
An adsorption ring (30) displaceably accommodated in the filter net (25) and having a plurality of adsorption holes (31); And
And cleaning means (40) installed to cause displacement of the adsorption ring (30) and discharging foreign matter through the adsorption hole (31)
The adsorption ring 30 is formed to have a constant thickness on a plane orthogonal to the hollow shaft 35 connected to the center,
The adsorption ring 30 further includes an arcuate groove 32 communicating with the adsorption hole 31 while maintaining an extended gap with the filter net 25 on the outer circumferential surface,
The hollow shaft 35 is provided so as to be watertight to the boss 21 of the body 20 or the support cap 26 of the filter net 25 via the mechanical seal 23,
The cleaning means 40 includes a driver 48 for causing the suction ring 30 to move up and down in the axial direction through the hollow shaft 35,
Wherein the cleaning means (40) is configured to additionally cause rotational movement of the adsorption ring (30) through the hollow shaft (35). delete delete delete delete delete delete

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