JPH0226524B2 - - Google Patents

Description

[Detailed Description of the Invention] [Field of Industrial Application] The present invention is applicable to waste liquids used for automatic cleaning of domestic wastewater, crude oil, heavy oil, other oils, kerosene, gasoline, various chemical liquids, various gases, etc. This invention relates to strainers that are applied to various fluids.

[Prior Art] A conventional strainer is a cylindrical casing with an inlet and an inlet interposed in a fluid flow path, and a porous cylindrical element inside the casing.

[Problem that the invention seeks to solve]

However, with such a conventional strainer, long objects such as lint that could pass through the cylindrical element pass through the strainer as they are, which poses a problem in that it becomes a hindrance to the next process.

The present invention solves this conventional problem by:
The present invention provides a strainer in which a cylindrical element has a breaking function.

[Means for solving problems]

The present invention provides a strainer that includes a porous cylindrical element inside a casing connected to a fluid flow path and a brush that comes into contact with the inner periphery of the cylindrical element, in which the cylindrical element is connected to an outer fixed element and a porous cylindrical element. This strainer is characterized in that it is formed of a double cylindrical body with a rotatable movable element slidably fitted therein.

〔Example〕

Embodiments of the present invention will be described using the drawings.

The strainer arranged in the fluid flow path comprises a cylindrical element 5, which is a porous filtering member, in a casing 4 with an inlet 1, an outlet 2 and an outlet 3 for trapped sediment, and further includes a cylindrical element 5, which is a porous filter element. 5 includes a brush 6 that comes into contact with the inner wall.

The casing 4 is a vertical cylindrical body, and is provided with annular partition walls 7 and 8 protruding from the middle and high positions of the inner surface at a height interval, and the upper end of the cylindrical element 5, which is open at both ends, is connected to the partition wall 7. and its lower end is located at the inner edge of the partition wall 8, so that a cylindrical permeate chamber 9 is formed between the cylindrical element 5 and the casing 4 between the partition walls 7 and 8. The outflow port 2 is provided in the permeated water chamber 9 . The bottom plate 10 of the casing 4 is formed of an inclined plate, and a bearing portion 1 for a rotating shaft 15 (described later) is provided at the center of the inner surface.
1 is fixed thereto, and a collar 26 concentric with the cylindrical element 5 is provided above the bearing portion 11 via a rotation preventing member 27. The discharge port 3 is provided at the lowest position of the side wall of the casing 4, and the inside of the casing 4 below the partition wall 8 is a deposition chamber 1.
2 is formed. A driving part 14 for a movable element 5-2, which will be described later, is provided on the lid 13 of the casing 4, and the inlet 1 is opened in the side wall of the casing 4 between the lid 13 and the partition wall 7. There is.

The cylindrical element 5 is a double inner and outer cylindrical body,
The outer cylindrical element is a fixed element 5-1 fixed to the partition walls 7 and 8, and the inner cylindrical element is a rotatable element that abuts the entire inner wall of the fixed element 5-1 and is slidably fitted with the inner wall. This is the movable element 5-2.

This movable element 5-2 is the fixed element 5
-1 through a boss 16, the rotating shaft 15 has an upper end protruding from the lid body 13 and is connected to the drive section 14, and is capable of rotating the hollow part of the collar 26. The lower end thereof is inserted into the bearing portion 11.

The boss 16 is fixed to the rotating shaft 15 with a set screw 18, and is connected to the upper end of the movable element 5-2 by means of radially projecting ribs 19.

The brush 6 is fixedly provided at a position where it comes into contact with the inner wall of the cylindrical element 5. That is, a flat brush mounting bracket 2 is attached to the collar 26 protruding from the bottom body 10.
Three brushes 8 are fixedly and protrudingly provided diagonally at intervals of 120 degrees from each other, and a brush 6 having a brush fixed to a substrate is attached to each brush mounting bracket 28 with bolts and nuts 20. The tips of the brushes are aligned so as to follow the curved surface of the inner wall of the cylindrical element 5.

The brush 6 has a length such that its upper end reaches the upper end of the element and its lower end reaches the lower end of the element, and the intersection angle θ with the collar axis is as small as possible for the fluid flow from the inlet 1 to the outlet 2. It is placed at an angle that provides only a certain amount of resistance.

In the figure, 21 is an electromagnetic ball valve, 22 is a gasket, 23 is a V gasket, 24 is a gland, 25 is a leg, and 29 is a pressure outlet. In addition, the drive unit 14
Although an electric motor is used, a manual switching lever 30 and a manual operation shaft are attached so that the brush 6 can be rotated manually.

Therefore, when fluid flows through the movable element 5-2 while rotating, a long object such as lint that may pass through the cylindrical element 5 is cut off by the fixed element 5-1 and the movable element 5-2. Since it is broken and flows through, it does not become a hindrance in the next process. The captured matter adhering to the cylindrical element 5 is peeled off and settled by the brush 6, so that the cylindrical element 5 is not clogged. The trapped substances deposited in the deposition chamber 12 are discharged from the discharge port 3 at a proper time.

Note that the rotation direction of the movable element 5-2 is the direction in which the captured object is guided downward by the brush 6 and the brush mounting bracket 28.

Further, the brush 6 and the brush mounting fittings 28 do not provide a large resistance to the fluid flow from the inlet 1 to the outlet 2, and do not impede smooth flow.

Furthermore, the brush 6 and the brush mounting bracket 28 peel off the captured object and guide it downward by the rotation of the movable element 5-2, so the resistance received from the fluid is less compared to raising and lowering a holding plate made of an axis orthogonal plate. Trapped substances can be deposited in an energy-saving manner and with an extremely simple configuration.

The example shown in FIG. 2 is an example in which a conical cylinder element 51 is used instead of the straight cylinder element 5 of FIG. 1.

Fixed element 51-1 and movable element 51
-2 is a conical cylinder whose diameter gradually decreases downward, and the movable element 51-2 is the fixed element 5.
1-1, and is attached to the rotating shaft 15 so as to be movable in the axial direction, that is, in the vertical direction, and can be moved between the fixed element 51-1 and the fixed element 51-1 by adjusting the vertical movement of the movable element 51-2. The gap with the movable element 51-2 can be adjusted.

Further, the brush 6 is also provided so that the tip of the brush follows the curved inner wall surface of the cylindrical element 51.
If necessary, the attachment to the brush attachment fitting 28 can be made movable in the radial direction.

It goes without saying that the same effect can be obtained by using a conical cylinder whose diameter gradually decreases upward.

Although the above description has been made using a vertical strainer, it can also be applied to a horizontal strainer. Further, the brush 6 may be one that brushes the entire circumferential surface of the inner wall of the cylindrical element 5 while the movable element 5-2 rotates, and may be one brush or a plurality of brushes may be separated in the vertical direction.

〔Effect of the invention〕

According to the present invention, it is possible to provide a strainer with an extremely simple structure without allowing elongated objects to flow through as they are, and because the strainer has a breaking function that helps prevent clogging, it is possible to improve fluid filtration processing.

[Brief explanation of drawings]

1 and 2 are longitudinal sectional views of different embodiments, respectively. 1... Inlet, 2... Outlet, 3... Outlet,
4... Casing, 5, 51... Cylindrical element, 5-1, 51-1... Fixed element, 5-
2,51-2...Movable element, 6...Brush, 7,8...Partition wall, 9...Permeated water chamber, 10...
Bottom plate, 11...Bearing section, 12...Deposition chamber, 13...
... Lid body, 14 ... Drive section, 15 ... Rotating shaft, 16
...Boss, 19...Rib, 26...Color, 27
... Rotation stopper member, 28 ... Brush mounting bracket.

Claims (1)

[Scope of Claims] 1. A strainer including a porous cylindrical element inside a casing connected to a fluid flow path and a brush that comes into contact with the inner periphery of the cylindrical element, wherein the cylindrical element is connected to an outer fixed element; A strainer characterized in that it is formed of a double cylindrical body with a rotatable movable element slidably fitted into the fixed element. 2. The strainer according to claim 1, wherein the cylindrical element is a conical cylinder. 3. The strainer according to claim 1 or 2, wherein the movable element is attached to a rotating shaft via a rib. 4. The strainer according to any one of claims 1 to 3, wherein the brush is fixed via a mounting bracket to a collar provided on the casing via a rotation preventing member. 5. The strainer according to claim 4, wherein the brush is attached to the collar at an angle so as to guide the caught object downward.