KR20140113508A - Inline strainer - Google Patents

Abstract

The present invention relates to an inline strainer coaxially inserted for a drain pipe line to achieve the reduction of entire size or efficiency improvement of foreign material collecting, the strainer comprising: a swirling flow generating part (3) which turns the liquid received from a housing (2) and an inlet part (7) into a swirling flow; a cylindrical filter element (4); a taper cone-shaped dust bin (5) connected to an opening end of an outlet part of the filter element; and a valve cap (6) for closing a discharging part (9) discharging foreign materials, wherein liquid which becomes the swirling flow by the swirling flow generating part (3) is passed and filtered outside from inside of the filter element (4), the filtered liquid is discharged to an outlet part (8) by going through outer circumstance passage (15) of the dust bin (5) and of the filter element, and the remaining foreign materials inside the filter element (4) are washed by the swirling flow and then flowed into the dust bin (5).

Description

Inline Strainer {INLINE STRAINER}

The present invention relates to an inline strainer for inserting a pesticide or a liquid such as water supplied to a plant into a pipeline to filter foreign substances (dust) in the liquid flowing through the pipeline.

As the prior art of the above-mentioned inline strainer, for example, those described in the following patent documents 1 and 2 are known.

The inline strainer disclosed in Patent Document 1 is inserted coaxially in the middle of a piping line, and a cyclone cylinder and a strainer element are provided inside a cylindrical housing having an inlet at one end and an outlet at the other end.

The inline strainer introduces a liquid into the inside of the housing through the inlet, inverts the flow of the liquid while swinging at the other end of the housing, and introduces the liquid into the inside of the cyclone cylinder. Then, the foreign matter is filtered by passing through the strainer element.

In the cyclone tubular body, the portion disposed near the inlet port of the housing is reduced in diameter toward the inlet port side of the housing, so that the foreign matter filtered by the strainer element collects in the reduced diameter portion. The tip of the diameter-reduced portion of the cyclone cylinder is provided with a dispensing opening for the foreign substance, and if necessary, the dispensing opening can be opened to take out the foreign substance.

On the other hand, the inline strainer disclosed in Patent Document 2 is inserted in the direction perpendicular to the axis with respect to the pipeline in the middle of the piping line, so that liquid introduced into the tubular body from the side absorption pipe is ejected from the nozzle, And the swirling flow is passed through a tubular filter disposed between the tubular body and the nozzle so as to flow out from the water pipe provided on the side opposite to the absorption pipe.

In the inline strainer of Patent Document 2, a taper cone type cyclone chamber is provided at the lower part of the main body, and the foreign matter filtered on the tubular filter is gathered in the inside of the cyclone chamber. At the bottom of the cyclone chamber, there is a discharge port for foreign substances that can be opened and closed.

Patent Document 1: Japanese Patent No. 4881977 Patent Document 2: Japanese Utility Model Publication No. 61-75807

In the inline strainer of Patent Document 1, since the flow of the liquid introduced into the housing is reversed at the other end side of the housing, it is difficult to reduce the size of the cyclone cylinder and the overall length tends to become longer.

Further, since the liquid whose flow has been reversed inside the housing reverses again after passing through the strainer element and is directed to the outflow port, the flow of liquid becomes weak near the tip of the diameter-reduced portion of the cyclone cylinder, It was also difficult to further improve the collection function.

Since the inline strainer of Patent Document 2 is inserted in the direction perpendicular to the axis of the pipe line, the inline strainer is more likely to be subjected to installation regulation than to be inserted coaxially with the pipe line.

The inline strainer also has a structure in which the generated swirling flow is hard to reach to the lower end of the cyclone chamber. The foreign matter having a weight is deposited on its own weight and deposited on the cyclone chamber. However, since the foreign matter which is likely to float in the liquid and is difficult to settle is adhered to the inner surface of the filter, it is not well recovered in the cyclone chamber, I think it is easy.

The present invention is directed to an inline strainer which is coaxially inserted into a piping line, as shown in Patent Document 1, to reduce the overall size and improve the efficiency of collection of foreign matter.

In order to solve the above problems, in the present invention, an inline strainer inserted in the longitudinal direction of the piping line is configured as follows.

Specifically, a tubular housing having an inlet port at one end, an outlet port at the other end, and a foreign matter outlet at the outer periphery in the longitudinal direction, and a tubular housing provided inside the inlet port side of the housing and introduced into the housing through an inlet port A tubular filter element to which the opening end of the swirling flow generating component is connected, and a tubular filter element extending in the longitudinal direction of the tubular line connected to the outlet end of the filter element And a valve cap for closing the foreign matter discharge port.

In addition, the dust collecting container was formed into a barrel having an outlet port side end portion closed, and an outlet port that can lead to the foreign matter discharge port at one of the outer peripheries.

The swirling flow generating component permeates the swirling liquid from the inside to the outside of the filter element and filters the filtered liquid so that the liquid after filtration flows between the outer periphery of the filter element and the inner surface of the housing So that foreign substances remaining in the filter element are washed away by the swirling flow and flow into the dust collecting container.

It is preferable that the inline strainer is formed into a taper cone shape whose diameter decreases from the inlet port side toward the outlet port side and the outlet is formed on the outer periphery of the outlet port side end portion.

Further, the valve cap has a valve seat which is in contact with the valve seat at the outlet end of the foreign matter discharge port inside the cap having a screw fitting structure, and the valve seat is pressed to the valve seat by rotation in the tightening direction The foreign matter discharge port is closed and the valve seat is separated from the valve seat by the rotation in the release direction so that the inside of the dust collecting container communicates with the hole opened to the outside formed in the bottom wall of the cap Do.

Preferably, the dust collecting container is provided with protrusions extending in the axial direction on its outer periphery, and the projections are inserted into guide grooves formed on the inner surface of the housing to perform positioning and rotation prevention.

In the inline strainer according to the present invention, the liquid introduced into the housing from the inlet port passes through the swirling flow generating component and becomes a swirling flow, and the swirling flow is introduced into the filter element.

The liquid introduced into the inside of the filter element flows through the filter element while flowing along the inner surface of the filter element and flows outwardly of the filter element while the opening end of the filter element is blocked by the dust collecting container, Then the foreign matter is filtered.

The foreign matter adhered to the inner surface of the filtered filter element is effectively washed by the swirling flow generated inside the filter element and is effectively blown into the dust collecting container by the swirling flow advancing. The effect of blowing foreign matter on the dust collecting container is superior to that of the conventional product because the dust collecting container is located in front of the traveling direction of the swirling flow going straight.

Further, since the foreign matter on the inner surface of the filter element is effectively washed away, the filter is not blocked well.

In addition, since the filtration is performed by passing the liquid introduced into the inside of the filter element through the filter element while pivoting the liquid, the length of the dust collecting container can be sufficiently shortened, thereby reducing the overall size of the strainer and reducing the cost It becomes possible.

1 is a sectional view showing an embodiment of an inline strainer according to the present invention;
Fig. 2 is a cross-sectional view taken along the line II-II in Fig. 1 (a part of the dust collector is broken).
3 is a cross-sectional view taken along line III-III in FIG. 2;
Fig. 4 is an exploded perspective view of the inline strainer of Fig. 1; Fig.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of an inline strainer according to the present invention will be described with reference to Figs.

As shown in Figs. 1 and 4, the illustrated inline strainer 1 includes a tubular housing 2, a swirling flow generating component 3, a tubular filter element 4, And the valve 5 and the valve cap 6 are combined.

The housing 2 has an inlet 7 at one end and an outlet 8 at the other end and a foreign matter outlet 9 on the outer periphery in the longitudinal direction. Reference numeral 10 denotes an end cap detachably attached to the outlet port side of the housing. An outlet port 8 is formed in the end cap 10.

The swirl flow generating component 3 is inserted into the inlet side end portion inside the housing 2. A plurality of twist passages 3a are formed in the predetermined direction in the vortical flow generating component 3. A force that rotates the liquid is imparted to the vortex flow generating component 3 by passing through the twist passages 3a, Is generated. Fig. 4 shows the swirl flow generating component 3 viewed from the upstream side and the swirl flow generating component 3 seen from the downstream side (this is shown in an enlarged scale).

Further, the swirling flow can be generated even when only one twist passage 3a is provided. The swirl flow generating component 3 is not limited to the example shown in the drawings, as long as it can generate swirling flow.

The filter element 4 is detachably connected to the swirl flow generating component 3 at its opening end on the inlet 7 side. A dust collecting container (5) is detachably connected to the opening end of the filter element (4) on the side of the outlet (8).

The collecting container 5 is formed in a tapered cone shape whose diameter gradually decreases from the inlet 7 side to the outlet 8 side. An outlet 11 of the dust collecting box 5 is connected to an outlet 9 of the dust collecting box 5 at one side of the outer periphery of the dust collecting box 5.

The dust collecting container 5 is positioned in such a position that the outlet 11 can lead to the foreign matter discharge port 9 and is held at the positioning point in FIGS. 2 and 3 A protrusion 12 extending in the axial direction is provided at a position rotated 180 degrees around the outer periphery and the protrusion 12 is inserted into a guide groove 13 formed in the inner surface of the housing 2, Crystal and rotation prevention are performed.

As shown in Fig. 2, the projection 12 projects the longitudinal end portion toward the downstream side (the outlet 8 side) of the pipe line rather than the closed end of the dust collecting container 5, The passage 14 is formed between the outer periphery of the dust collecting container 5 and the inner surface of the end cap 10 in a state of being brought into contact with the inner surface of the cap 10. [

The passage 14 extends through a passage 15 formed between the outer periphery of the filter element 4 and the dust collecting container 5 and the inner surface of the housing 2.

The valve cap 6 adopts a configuration in which a valve seat 6b is provided inside a cap 6a having a threaded engagement structure.

The foreign matter discharge port 9 is constituted by a hole of a branch pipe 16 protruding outside the housing and an outlet end of the foreign matter discharge port 9 (end surface of the branch pipe 16) And the foreign matter outlet 9 is opened and closed by contacting and separating the valve seat 6b therefrom.

When the cap 6a screwed on the outer periphery of the branch pipe 16 is rotated in the tightening direction, the valve seat 6b is pressed to the valve seat so as to close the foreign matter discharge port 9 and rotate in the release direction, (6b) is separated from the valve seat so that the foreign matter discharge port (9) is opened.

The dust collecting container 5 communicates with the hole 17 and communicates with the dust collecting container 5 when the valve seat 6b is separated from the valve seat. The foreign matter collected in the inside of the container is discharged to the outside.

The swirling flow generated inside the filter element 4 flows to the foreign matter discharge port 9 and the swirling flow that is collected inside the dust collecting container 5 by the swirling flow The foreign matter is instantaneously discharged. Therefore, even if the foreign matter is discharged while flowing the liquid through the piping line, the liquid is not leaked in a large amount.

The illustrated valve cap 6 is excellent in usability because the foreign matter outlet 9 can be opened and closed without completely removing the cap 6a. However, the valve cap 6 is detachably attached to the branch pipe 16, It may be a structure for opening and closing the discharge port 9.

When the collected dust collecting container 5 is in the form of a tapered cone whose diameter gradually decreases from the inlet port 7 side to the outlet port 8 side and when collected foreign matter is discharged using the flow of the liquid, The flow velocity is increased and the discharge of the foreign matter is smooth. However, the object of collecting and discharging the foreign matter is achieved even if it is not a taper cone shape.

Reference numeral 18 in Fig. 1 denotes a female-threaded joint, and 19 denotes a male-threaded joint, which are provided for the purpose of connecting the housing 2 to the piping line L. The connection of the housing 2 to the piping line L may be performed by providing a flange or the like, and the illustrated joint is not necessarily required.

Reference numeral 20 in Fig. 1 denotes an O-ring for sealing between the swirl flow generating component 3 and the housing 2, reference numeral 21 denotes a seal packing to be sandwiched between the end cap 10 and the housing 2, 22 is a seal packing sandwiched between the end cap 10 and the cap nut for pipeline line connection screwed to the male screw attaching joint. These are not a feature of the present invention.

INDUSTRIAL APPLICABILITY The inline strainer according to the present invention is small in size and can efficiently collect and discharge foreign matter mixed in a liquid. As a result, it is possible to effectively utilize the stored water of the rainwater into which the foreign substance is mixed.

1: inline strainer 2: housing
3: Swirl flow generating part 3a: Twist passage
4: Filter element 5: House dustbin
6: valve cap 6a: cap
6b: valve seat 7: inlet
8: Outlet 9: Foreign matter outlet
10: end cap of housing 11: outlet of dust collecting box
12: projection 13: guide groove
14, 15: passage 16: branch pipe
17: Hole 18: Female threaded joint
19: Joint with male thread 20: O-ring
21, 22: Seal packing L: Piping line

Claims (4)

An inline strainer inserted in the longitudinal direction of a piping line (L)
(2) having an inlet (7) at one end, an outlet (8) at the other end and a foreign matter outlet (9) around the outer periphery in the longitudinal direction, and a tubular housing A swirling flow generating component (3) provided inside the swirling flow generating component (3) for making the liquid introduced into the housing through the inlet port into a swirling flow, a tubular filter element (4) to which the opening end of the swirling flow generating component is connected, (5) extending in the lengthwise direction of a piping line connected to an outlet end of the filter element and a valve cap (6) for closing the foreign matter discharge port (9)
The dust collecting container (5) is a box having an outlet (11) formed at one of the outer peripheries and capable of leading to the foreign matter discharge port (9)
The swirling flow generating component 3 permeates the swirling liquid from the inside to the outside of the filter element 4 and filters the liquid so that the liquid after filtration passes through the filter element 4 and the dust collecting container 5, Passes through a passage (15) formed between the outer periphery of the filter element (4) and the inner surface of the housing (2) and flows into the outlet (8), and the foreign matter left in the filter element (4) So as to flow into the analgesic (5). The exhaust gas purifier of claim 1, wherein the dust collecting container (5) is formed in a taper cone shape whose diameter decreases from the inlet side (7) to the outlet side (8) (11) is formed. The valve seat according to claim 1 or 2, wherein the valve cap (6) is provided with a valve seat (6b) which is in contact with the valve seat at the outlet end of the foreign matter discharge port (9) The valve seat 6b is pressed against the valve seat by the rotation in the tightening direction to close the foreign matter discharge port 9 and the valve seat 6b is rotated by the rotation in the release direction, And the inside of the dust collecting container (5) is separated from the left so as to communicate with an externally opened hole (17) formed in a bottom wall of the cap (6a). The dust collecting container according to any one of claims 1 to 3, characterized in that a protrusion (12) extending in the axial direction is formed on the outer periphery of the dust collecting container (5) and the protrusion is formed in a guide groove 13 so as to position and prevent rotation of the dust collecting container (5).

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