JPH0659369B2 - Filter device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Industrial field of application) The present invention separates fine particles contained in a fluid or gas, such as ferromagnetic fine particles and paramagnetic fine particles (eg, corrosion products mainly composed of iron oxide). The present invention relates to a filter device to be removed.

(Prior Art) Conventionally, as a filter device, a filter device in which a plurality of filter elements are arranged in series in a fluid flow path is known.

(Problems to be Solved by the Invention) According to the above-described conventional filter device, when the particles separated from the liquid or gas are accumulated in the filter element, the cleaning air or the cleaning liquid is caused to flow to remove the particles. Since the fine particles separated from the filter element have to be removed via another filter element connected in series, there is a problem that the cleaning efficiency is low.

An object of the present invention is to obtain a filter device having higher cleaning efficiency than the conventional filter device.

(Means for Solving the Problems) In order to achieve the above object, the filter device according to claim 1 is a filter device in which a plurality of or a plurality of sets of filter elements are arranged in series in a fluid passage. The gap between one or one set of filter elements adjacent to one or one set of filter elements is connected to a cleaning fluid outflow passage which is opened at the time of cleaning the filter element, and a filter is provided in a fluid flow path downstream of the filter element. A filter device provided with a valve that closes when cleaning an element, wherein the one or one set of filter elements and one or one set of filter elements adjacent to each other are laminated via a plate made of a non-magnetic material, and the plate Is a number of through-holes that communicate the stacked filter elements, and the through-holes that are formed on both main surfaces and are adjacent to each other. And a plurality of holes, one end of which is connected to the groove of the peripheral edge of the plate and the other end of which is connected to the cleaning fluid outflow passage. A filter device according to a second aspect is the filter device according to the first aspect, wherein the filter element is a porous plate made of a magnetic material, and an electromagnetic coil for magnetizing the filter element is provided.

(Operation) According to the filter device of the first aspect, the particles adsorbed by the filter element for each one or one set of filter elements are directly discharged to the cleaning fluid outflow passage. Therefore, the filter element can be efficiently washed.

In addition, since a plurality of or a plurality of sets of filter elements are laminated via plates made of a non-magnetic material, they are retained with high mechanical strength and can withstand high-pressure fluid. Further, since the grooves connecting the through holes are formed on both main surfaces of the plate having a large number of through holes, the fluid is distributed almost evenly over the entire surface of the filter element, so that the adsorption of fine particles to the filter element is prevented. Averaged. When a pressurized cleaning fluid is flowed, the filter element can be cleaned evenly, and since the filter element and the plate are not in contact with each other at the through hole and groove, the filter element is A slight vibration occurs in this portion due to the flow of, and the attached fine particles are easily released, and the cleaning efficiency is increased.

(Example) Hereinafter, an example of the present invention applied to a filter device suitable for separating and removing magnetic particles contained in a fluid will be described with reference to the drawings.

In FIG. 1, reference numeral 1 denotes one or a set of two to five stacked filter elements, which is a plate 2 (later made of SUS304) made of a non-magnetic material (for example, SUS304) in which a large number of through holes and grooves are formed. It will be described in detail) and is housed and held in a case body 3 made of a non-magnetic material by being laminated in multiple stages. At one end of the case body 3 is a case head 4 made of magnetic material.
The case head 4 is attached with a canister 6 made of a non-magnetic material having a canister bottom 5 made of a magnetic material fixed to one end. The canister bottom 5 is connected to a pipe 8 through which a fluid or gas containing fine particles flows in via _one branch 71 of the pipe 7, while the case head 4 is connected to an outflow pipe 9 made of a non-magnetic material. Thus, the liquid or gas containing the fine particles is discharged from the pipe 8 through the pipe body.
7, hole 10 in canister bottom 4, through hole in plate 2,
The filter element 1, the through hole 11 of the case head 4 and the outflow pipe 9 are allowed to flow as indicated by a thick arrow.

The filter element 1 is a porous plate made of a magnetic material, for example, having a large number of holes with a diameter of 60 μm and a thickness of, for example, 50 μm. (See the specification of Utility Model Registration No. 1665285 for details). An electromagnetic coil 12 for magnetizing the filter element 1 is wound around a peripheral surface of a canister 6 made of a non-magnetic material, and when an electric current is passed through the canister 6, it is composed of a cylindrical body surrounding the electromagnetic coil 12 and upper and lower cover plates thereof. Magnetic field lines flow in the magnetic circuit composed of the frame 13 made of magnetic material, the case head 4 made of magnetic material, the filter element 1, and the canister bottom 5 made of magnetic material as indicated by the dotted arrow, and the film element 1 Is magnetized. Since there is no magnetic material between the case head 4 and the filter element 1 and between the filter element 1 and the canister bottom 5, magnetic field lines are diffused between the case head 4 and the canister bottom 5 to reduce the magnetic field strength. Therefore, the volume of the case head 4 and the canister bottom 5 is formed to be large so as to prevent the decrease of the magnetic field strength and allow the magnetic force lines to pass through the entire area of the filter element 1.

Inside the through hole 11 of the case head 4, there is provided a valve 16 capable of closing the flow path by operating an operating member 15 fixed to one end of a shaft 14 made of a non-magnetic material. 3 and the case head 4 have through holes 17 ₁ and 17 ₂ connected to the through holes and grooves of the plate 2 between the filter elements 1 and the through holes 17 ₁ and 17 ₂ are ring-shaped grooves of the seat plate 18. 19 is connected to the conduit 20 for discharging the cleaning gas or cleaning water through, also in the pipe body 7 and the other branch passage 7 _2, conduits for flowing cleaning water or cleaning gas
21 is connected.

When cleaning the filter element 1, stop the flow of the fluid containing fine particles from the pipe 8 into the pipe 7, and
16 is closed, the energization of the electromagnetic coil is stopped, demagnetization is performed as a residual magnetism removing step that remains in the magnetic circuit, and cleaning water or cleaning gas is flown into the tube body 7 from the conduit 21.

Then, the cleaning gas or cleaning water is used for the holes in the canister bottom 5.
10 through the filter element 1 in the case body 3 and the through holes and grooves of the plates 2 and through the holes 17 ₁ and 17 ₂ of the case body 3 and the case head 4 to the pipe line 20 as shown by a thin arrow. Flowing.

A case body 3 and the case head 4 will be described the housing the plate 2 configuration of these in more detail by Figure 2 to Figure 5, plate 2 ₉ of the upper and lower ends of FIG. 2 and 2 ₁
Except for the above, the plate 2 has a large number of through holes 22 (for example, a diameter of 5 mm) opened on both main surfaces A and B, and both main surfaces A and B, respectively, as clearly shown in FIGS. 4 and 5. Formed through hole
Longitudinal and lateral grooves 23 connecting 22 to each other, a ring-shaped groove 24 formed on the peripheral surface, and four L-shaped through holes 25 opening to the main surface B and the groove 23 are formed. . Plate 2 ₉ arranged at the upper end of the second view are those no grooves 23 on the main surface A, the plate 2 ₁ to place the lower end has no grooves 23 on the main surface B, also as L-shaped hole 25 is not Is. Plates 2, 2 ₁ , 2 ₉
2 are arranged with the main surface A facing upward in FIG.

According to the configuration of the plate 2, 2 _1, 2 _9, in passing a fluid containing particulates to the filter apparatus, the fluid plates 2,
Since flows together through the 2 _1, 2 ₉ of the through-hole 22 into the groove 23, is substantially evenly distributed on the filter element 1 entirely,
The adsorption of fine particles on the filter element 1 is averaged.

The case body 3, as shown in FIGS. 2 and 3, one end in staggered positions circumferentially laminated plates 2, 2 ₉ to the distance of each corresponding and equal intervals, for example, 45 degrees from each other open and the other end above the through-hole 17 ₁ for example, eight to open the case head 4 coupling surface (17 _1a to 17 _1h) are formed, in the case head 4 through holes 17 ₁ (17 _1a to 17 _1h) communicating, opening for example eight holes 17 ₂ (17 _2a ~17 _2h) are formed in upper end.

Filter element 1, case body 3 and case head
Since 4 is configured as above, when cleaning filter element 1, cleaning gas or cleaning water is
2 through the through holes 22 of 2, ₁ , 2 and ₉ to radially flow in the groove 23,
A ring-shaped groove 24 formed on the peripheral surface from, for example, four through holes 25 at the peripheral end, and through holes 17 _{1a to} 17 _1h and 17 _{2a to} 17 _2h of the case body 3 and the case head 4 connected to the groove 24 are formed. Through the pipe line 20, and the cleaning gas or cleaning water flows through the filter element.
1 Almost evenly distributed over the entire surface, cleaning is performed on average.

When the magnetic fine particles contained in the fluid are paramagnetic fine particles, the filter element 1 lowers the separation and removal efficiency of the fine particles. In this case, therefore, the duct 8 is provided with a magnetizing device 26 including an electromagnetic coil or a magnet. So that the paramagnetic particles are magnetized before flowing into the filter element 1. By doing so, the paramagnetic particles having residual magnetism are easily adsorbed by the filter element 1, and the adsorption efficiency can be improved.

(Effects of the Invention) Since the present invention has the above-mentioned configuration, it has the effect that the filter element to which the fine particles in the fluid adhere can be cleaned with higher efficiency than the conventional one.

[Brief description of drawings]

1 is a sectional view of an embodiment of the present invention, FIG. 2 is a sectional view of the case body and the case head, FIG. 3 is a plan view of the case head, FIG. 4 is a plan view of the plate, and FIG. FIG. 6 is a sectional view taken along the line VV of FIG. 4, and FIG. 6 is a diagram of a main part of the modified example. 1 …… Filter element 2, 2 ₁ , 2 ₉ …… Plate, 12 …… Electromagnetic coil 16 …… Valve, 20 …… Pipe line 22 …… Through hole, 23 …… Groove 24 …… Groove, 25 …… Through Hole

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁵ Identification number Office reference number FI technical display location B01D 35/06 A 35/16 6953-4D 46/10 C 7446-4D A 7446-4D 46/12 7446-4D B03C 1/02 Z

Claims (2)

[Claims] 1. A plurality of or a plurality of sets of filter elements are arranged in series in a fluid flow path, and one or a set of filter elements and a gap between the adjacent one or one set of filter elements are cleaned. In a filter device, which is connected to a cleaning fluid outflow passage which is opened at times, and which is provided with a valve which is closed in a fluid flow path downstream of the filter element when the filter element is washed, is adjacent to the one or one set of filter elements. One or a set of filter elements are laminated via plates made of a non-magnetic material, and the plate is formed with a large number of through holes communicating the laminated filter elements with each other and is formed on both main surfaces and is adjacent to each other. It has a groove connecting the through holes, and a plurality of holes, one end of which is connected to the groove on the peripheral edge of the plate and the other end of which is connected to the cleaning fluid outflow passage. Filter apparatus according to claim and. 2. The filter device according to claim 1, wherein the filter element is a porous plate made of a magnetic material, and an electromagnetic coil for magnetizing the filter element is provided.