KR102133058B1 - Inline strainer - Google Patents

Abstract

An object of the present invention is to provide an inline strainer that is coaxially inserted with respect to a piping line, so that overall size reduction and improvement in the recovery efficiency of foreign matter can be achieved.
The housing 2, the swirling flow generating part 3 which makes the liquid introduced into the housing 2 from the inlet 7 into swirl flow, the cylindrical filter element 4, and the outlet side of the filter element It is provided with a taper-cone dust collector (5) connected to the ball end, and a valve cap (6) for closing the foreign material outlet (9), and the liquid that has been swirled by the swirl flow generating part (3) is a filter element ( 4) from the inside to the outside to filter, and the filtered liquid flows through the filter element and the passage 15 around the outside of the dust collector 5 to the outlet 8, and the inside of the filter element 4 The remaining foreign matter was washed with a swirling flow to flow into the dust collector (5).

Description

Inline strainer {INLINE STRAINER}

The present invention relates to an inline strainer that is inserted into a pipe line through which liquids such as supply water for pesticides or plants pass, and filters foreign matter (dust) in the liquid flowing through the pipe line.

As the prior art of the inline strainer, for example, those described in Patent Documents 1 and 2 below are known.

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

This inline strainer introduces liquid into the interior of the housing through the inlet, and reverses the flow of the liquid while turning at the other end side of the housing to introduce the liquid inside the cyclone cylinder. Then, the foreign matter is filtered by passing through the strainer element.

In addition, the cyclone cylinder body reduced the diameter of the portion disposed near the inlet of the housing toward the inlet of the housing, so that foreign matter filtered by the strainer element gathered in the diameter reducing portion. A discharging port for foreign matter is formed at the tip of the diameter reduction portion of the cyclone cylinder, and if necessary, the discharging foreign matter can be taken out by opening the discharging port.

On the other hand, the inline strainer disclosed in Patent Document 2 is inserted in the axial perpendicular direction to the pipe line in the middle of the pipe line, and ejects liquid introduced into the tubular body from the absorption pipe on the side from the nozzle, thereby circulating swirl flow. It is supposed to generate and pass the swirling flow through a cylindrical filter disposed between the cylindrical body and the nozzle, and flow out from the water supply pipe provided on the side opposite to the absorption pipe.

In the inline strainer of Patent Document 2, a tapered cone-shaped cyclone chamber is provided at the bottom of the main body, and foreign matter filtered through the cylindrical filter is collected inside the cyclone chamber. At the bottom of the cyclone chamber, there is an outlet for opening and closing of foreign matter.

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 liquid introduced into the inside of the housing is inverted from the other end side of the housing, it is difficult to reduce the size of the cyclone cylinder, and the overall length tends to be long.

In addition, since the liquid whose flow is reversed inside the housing is reversed again after passing through the strainer element, and is directed to the outlet, the flow of the liquid is weakened in the vicinity of the tip of the diameter reduction portion of the cyclone cylinder, and filtered foreign matter is near the outlet. It was also difficult to further improve the collecting function.

Since the inline strainer of Patent Document 2 is inserted in the direction perpendicular to the piping line, it is easier to be subject to installation restrictions compared to being inserted coaxially with the piping line.

Moreover, this inline strainer also has a structure in which the generated swirl flow is difficult to reach to the lower end of the cyclone chamber. The foreign matter with the weight is settled by its own weight and deposited in the cyclone chamber, but the foreign matter that is easy to float in the liquid and is difficult to settle is not easily recovered in the cyclone chamber because it adheres to the inner surface of the filter, so that the filter is clogged. I think it's easy.

The present invention has an object to be able to reduce the overall size, improve the recovery efficiency of foreign substances, and the like, with respect to an inline strainer that is coaxially inserted into a piping line, as Patent Document 1 indicates.

In order to solve the said subject, in this invention, the inline strainer inserted in the middle of the longitudinal direction of a piping line was comprised as follows.

Specifically, a cylindrical housing having an inlet port at one end, an outlet port at the other end, and a foreign material outlet port at an outer circumference in the middle of the longitudinal direction, and installed inside the inlet side of the housing and introduced into the housing through the inlet port A swirling flow generating part that rotates the liquid, a cylindrical filter element to which the opening end on the inlet side is connected to the swirling flow generating part, and a pipe line connected to the opening end on the outlet side of the filter element are extended in the longitudinal direction. A dust collecting passage and a valve cap for closing the foreign material outlet were provided.

In addition, the dust collecting container was made into a container in which the outlet-side end is closed and an outlet that can lead to the foreign material outlet is formed in one place around the outside.

Then, the liquid that has been swirled by the swirling-generating component is filtered by permeating from the inside of the filter element toward the outside, and the filtered liquid is disposed between the outer periphery of the filter element and the dust collector and the inner surface of the housing. The passage was formed to flow through the outlet, and the foreign matter remaining inside the filter element was washed by swirling flow to flow into the dust collector.

The inline strainer preferably forms the dust collecting cylinder in a tapered cone shape that decreases in diameter from the inlet side toward the outlet side, and is preferably a barrel in which the outlet is formed at the outer circumference of the outlet side end.

Further, as the valve cap, there is provided a valve seat which is in contact with and separated from the valve seat of the outlet end of the foreign material outlet inside the cap of the screw fitting structure, and the valve seat is pressed against the valve seat by rotation in the tightening direction. It is preferable that the foreign material outlet is closed, and that the valve seat is separated from the valve seat by rotation in the unlocking direction, so that the inside of the dust collector is configured to communicate with an open hole formed in the bottom wall of the cap. Do.

Further, it is preferable that the dust collector is provided with projections extending in the axial direction around the outside, and inserted into the guide grooves formed on the inner surface of the housing to prevent positioning and rotation.

In the inline strainer of the present invention, the liquid introduced into the interior of the housing from the inlet passes through the swirl flow generating part to become swirl flow, and the swirl flow is introduced inside the filter element.

Since the liquid introduced into the inside of the filter element is blocked by the dust collector at the outlet side of the outlet of the filter element, while passing along the inner surface of the filter element, it passes through the filter element and flows out of the filter element while going straight, At that time, foreign matter is filtered.

In addition, the foreign matter attached 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 collector by riding the advancing swirling flow. Since the dust collector is in the forward direction of the swirling flow going straight, the effect of blowing foreign matter into the dust collector is superior to that of the conventional product.

In addition, the foreign matter on the inner surface of the filter element is effectively washed, so that the filter is not blocked well.

In addition, since the filter element is filtered while rotating the liquid introduced inside the filter element, the length of the dust collector can be sufficiently shortened, thereby reducing the overall size of the strainer and reducing the cost. It becomes possible.

1 is a cross-sectional view showing an embodiment of the inline strainer of the present invention.
FIG. 2 is a cross-sectional view along II-II of FIG. 1 (the dust collector is partially broken).
3 is a cross-sectional view along III-III of FIG. 2;
Figure 4 is an exploded perspective view of the inline strainer of Figure 1;

Hereinafter, the embodiment of the inline strainer of this invention is demonstrated based on attached FIGS. 1-4.

1 and 4, the illustrated inline strainer 1 includes a cylindrical housing 2, a swirl flow generating part 3, a cylindrical filter element 4, and a house. It consists of a combination of the analgesic 5 and the valve cap 6.

The housing 2 has an inlet 7 at one end, an outlet 8 at the other end, and a foreign material outlet 9 around the outer circumference in the longitudinal direction. Reference numeral 10 is an end cap detachably attached to the outlet side of the housing, and an outlet 8 is formed in the end cap 10.

The swirl flow generation component 3 is inserted into the inlet side end inside the housing 2. A plurality of twist passages 3a are formed in the swirl flow generation part 3 in a predetermined direction, and a rotational force is applied to the liquid by passing through the twist passages 3a, so that the swirl flows inside the filter element 4 Is created. In FIG. 4, the view of the swirl flow generation part 3 seen from the upstream side and the view seen from the downstream side (this is shown in an enlarged view) are shown together.

In addition, swirl flow can be produced even if there is only one twist passage 3a. The swirl flow generation component 3 may be any one that can generate swirl flow, and is not limited to the illustrated form.

In the filter element 4, the opening end on the inlet 7 side is detachably connected to the swirl flow generation component 3. In addition, the dust collector 5 is detachably connected to the opening end of the filter element 4 on the outlet 8 side.

The dust collecting container 5 is a tapered cone-shaped cylinder which gradually decreases in diameter from the inlet 7 side toward the outlet 8 side. The outlet-side end of the dust collector 5 is closed, and an outlet 11 that can lead to the foreign material discharge port 9 is formed at one place around the outside of the dust collector 5.

This dust collecting container 5 is positioned in a position where the outlet 11 can lead to the foreign material discharge port 9, and, in addition, in FIGS. 2 and 3, to maintain the container at the positioning point. As shown, a projection 12 extending in the axial direction is provided at a position rotated 180° around the outer circumference, and the projection 12 is inserted into the guide groove 13 formed on the inner surface of the housing 2 to position Crystal and rotation are prevented.

As shown in Fig. 2, the projection 12 protrudes the end portion in the longitudinal direction toward the downstream side (the outlet 8 side) of the pipe line rather than the closed end of the dust collector 5, and the tip end of the protrusion is end portion. A passage 14 is formed between the outer circumference of the dust collecting container 5 and the inner surface of the end cap 10 in a state in which the cap 10 is in contact with the inner surface.

The passage 14 passes 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.

As for the valve cap 6, what provided the valve seat 6b in the inside of the cap 6a of the screw fitting structure is adopted.

The foreign material discharge port 9 is composed of holes in the branch pipe 16 formed to protrude outside the housing, and the outlet end (end face of the branch pipe 16) of the foreign material discharge port 9 is used as a valve seat. Thereby, the valve seat 6b is contact-separated to open and close the foreign material discharge port 9.

When the cap 6a screwed around the outer circumference of the branch pipe 16 is rotated in the tightening direction, the valve seat 6b is pressed against the valve seat to close the foreign material outlet 9, and when rotated in the unlocking direction, the valve seat (6b) is separated from the valve seat, and the foreign material outlet 9 is opened.

The bottom wall of the cap 6a is formed with a hole 17 open to the outside, and when the valve seat 6b is separated from the valve seat, the dust collector 5 communicates with the hole 17, and the dust collector 5 The foreign matter collected in the interior is discharged to the outside.

When discharging foreign matters while the liquid is flowing through the piping line, the swirl flow generated inside the filter element 4 flows to the foreign matter discharge port 9, and is collected inside the dust collector 5 by the swirl flow. Foreign matter is discharged instantaneously. Therefore, even if the foreign matter is discharged while flowing the liquid in the pipe line, the liquid does not leak in a large amount.

In addition, although the illustrated valve cap 6 can open and close the foreign material outlet 9 without completely removing the cap 6a, the usability is excellent, but the valve cap 6 is attached to and detached from the branch pipe 16. It may be of a structure that opens and closes the outlet 9.

In addition, when the dust collector 5 has a shape shown in the figure, that is, a tapered cone shape in which the diameter decreases from the inlet 7 side toward the outlet 8 side, the collected foreign matter is discharged using the flow of liquid. The flow rate is increased, and the effect of smoothly discharging foreign matter can be obtained, but the purpose of recovery and discharging of foreign matter is achieved even if the shape is not tapered.

Reference numeral 18 in FIG. 1 denotes a joint with a female thread, and reference numeral 19 denotes a joint with a male thread, 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 required.

Reference numeral 20 in FIG. 1 denotes an O-ring that seals between the swirl flow generating component 3 and the housing 2, and reference numeral 21 denotes a seal packing sandwiched between the end cap 10 and the housing 2, 22 is a seal packing fitted between the end cap 10 and the cap nut for pipe line connection screwed to the male threaded joint. These are also not features of the invention.

The inline strainer of the present invention is compact and can efficiently collect and discharge foreign substances mixed in a liquid. Accordingly, it is possible to effectively utilize the storage water of rainwater mixed with foreign matter.

1: inline strainer 2: housing
3: Swirl flow generation part 3a: Twist passage
4: filter element 5: dust collector
6: valve cap 6a: cap
6b: valve seat 7: inlet
8: Outlet 9: Foreign material outlet
10: end cap of the housing 11: outlet of the dust collector
12: projection 13: guide groove
14, 15: passage 16: branch
17: hole 18: joint with female thread
19: joint with male thread 20: O-ring
21, 22: Seal packing L: Piping line

Claims (5)

As an inline strainer inserted in the longitudinal direction of the pipe line (L),
A cylindrical housing (2) having an inlet (7) at one end, an outlet (8) at the other end, and a foreign material outlet (9) around the outer circumference in the longitudinal direction, and the inlet (7) side of the housing A swirling flow generating part (3) that is installed inside to make the liquid introduced into the housing through the inlet flow into a swirling flow; and a cylindrical filter element (4) to which the opening end of the inlet side is connected to the swirling generating part, A dust collector (5) extending in the longitudinal direction of the pipe line connected to the opening end on the outlet side of the filter element, and a valve cap (6) for closing the foreign matter outlet (9) are provided.
The dust collecting container 5 is a container having an outlet 11 that can lead to the foreign material discharge port 9 in one place around the outside,
The liquid that has been swirled by the swirling flow generating part 3 is filtered by permeating from the inside of the filter element 4 toward the outside, and the filtered liquid is filtered through the filter element 4 and the dust collector 5 Pass the passage 15 formed between the outer circumference of the outer surface and the inner surface of the housing 2 to flow through the outlet 8, and wash away the foreign matter remaining inside the filter element 4 by swirling. It is intended to flow into pain relief (5),
The dust collector (5) is formed into a tapered cone shape in which the diameter decreases as it goes from the inlet side (7) to the outlet side (8), and the outlet (11) is formed around the outer circumference of the outlet side end. One inline strainer. delete 2. The valve cap (6) according to claim 1, wherein, as the valve cap (6), a valve seat (6b) is provided inside the cap (6a) of the screw-fitting structure, which is separated from the valve seat at the outlet end of the foreign material outlet (9), The valve seat 6b is pressed against the valve seat by rotation in the tightening direction, and the foreign material outlet 9 is closed, and the valve seat 6b is separated from the valve seat by rotation in the unlocking direction. The inline strainer using the one configured to communicate with the hole 17 which is open to the outside formed in the bottom wall of the cap 6a. The dust collecting tube according to claim 1, wherein a protrusion (12) extending in an axial direction is formed around an outer circumference of the dust collecting tube (5), and the protrusion is inserted into a guide groove (13) formed on the inner surface of the housing. (5) An inline strainer intended to perform positioning and rotation prevention. The dust collecting tube according to claim 3, wherein a protrusion (12) extending in an axial direction is formed around an outer circumference of the dust collecting container (5), and the protrusion is inserted into a guide groove (13) formed on the inner surface of the housing. (5) An inline strainer intended to perform positioning and rotation prevention.

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