JPH08309137A - Cartridge filter element for dust collector - Google Patents

Abstract

PURPOSE: To increase the air flow capacity of a cartridge filter element for a dust collector. CONSTITUTION: Into a first cylindrical filter medium 10 is inserted a second cylindrical filter medium 20 which is shorter and thinner than the first filter medium 10 with the ends on one side trued up. On this side, the outside end of the first filter medium 10 is closed, while the inside end of the second filter medium 20 is opened. On the other side, the outside end of the first filter medium 10 is opened, but the inside end of the second filter medium 20 is closed.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cartridge filter element for filtration used in a dust collector.

[0002]

2. Description of the Related Art In a dust collector, a cartridge filter element is used to separate solid matter such as dust from sucked air.

6 and 7 are views showing an example of this kind of cartridge filter element (hereinafter, simply referred to as an element). This element has a configuration in which one end of a cylindrical filter medium 60 is a closed portion 61 and the other end is an open portion 62, and air introduced from the outer periphery of the filter medium 60 passes through the filter medium to separate solids. And is discharged from the inner periphery of the filter medium toward the open portion 62 (in the figure, the flow of air before filtration is indicated by a solid arrow,
The flow of air after filtration is indicated by the dotted arrow. ).

[0004]

By the way, since the dust collector can be made compact with respect to a predetermined air volume that can be processed, the cost of the can and the power cost can be reduced, so that the elements used for the dust collector can be made compact. Was requested.

In this case, needless to say, a certain filtration area is required to process a predetermined air volume. For example, in order to process a flow rate of 100 m ³ / min, a filter medium area of 100 m ² is generally required.

In view of the above, in the above-mentioned prior art element, the filter medium has a cylindrical shape in order to make it compact, and the filter medium is bent in a pleated shape in order to maximize the filter medium area within a fixed volume. Was adopted.

In view of the above problems of the prior art, it is an object of the present invention to provide an element that is more compact with respect to a predetermined air volume that can be processed.

[0008]

That is, the element of the present invention has a constitution in which a tubular second filter medium having a shorter overall length and a smaller diameter is arranged inside one end of a tubular first filter medium with one end aligned. In these filter media, the end of the first outer filter medium is closed at one end where the ends are aligned, the end of the second inner filter medium is opened, and the end of the first outer filter medium is at the other end. Is opened and the end of the inner second filter medium is closed.

As a second invention, which is a further development of the above invention (hereinafter, the above invention will be referred to as a first invention), as a second invention, the total length is shorter and the diameter is smaller inside the first cylindrical filter medium. The second cylindrical filter medium of is arranged with one end aligned and the second
Inside the filter medium, a cylindrical third filter medium having a smaller diameter than this is arranged with one end aligned, and these filter media have the ends of the outermost first filter medium and the innermost end at the one end where the ends are aligned. The end of the third filter medium is closed, the end of the intermediate second filter medium is opened, and the end of the outermost first filter medium and the end of the innermost third filter medium are opened at the other end. Also disclosed is an element characterized in that the end of the intermediate second filter medium is closed.

[0010]

Thus, according to the present invention, since a plurality of cylindrical filter media are provided within a constant volume, the effect of obtaining a larger filter media area while maintaining a constant volume is produced.

For example, in the case of the first aspect of the invention, assuming the element having the following specifications, the filter medium area is calculated as follows. 1 Element size: 130φ × 500ι 2 1st filter medium area: 0.9m ² ＝ 15mmH × 500W × 60P 3 2nd filter medium area: 0.315m ² ＝ 15mmH × 350W × 30P Note / φ = element diameter ι ＝ element Height H = width of pleats of filter media pleats W = height of pleats of filter media P = number of pleats of filter media pleats

Therefore, in this case, the area of the first filter medium is 0.9 m ²
On the other hand, the area of the second filter medium is 0.315 m ² , which makes it possible to increase the filter medium area by about 35% within a fixed volume. In other words, if the filter medium area is the same as the conventional one, it is possible to obtain the same work amount with an element having a volume of about 2/3.

On the other hand, the void volume on the inner circumference of the first filter medium is reduced by the presence of the second filter medium. For example, in the above case, the void volume of the first filter medium is 3925cc,
If the void volume of the filter medium is 1758 cc, the void volume of the first filter medium will be reduced by about 45%. This means that the amount of high-pressure air for backflow cleaning of the element can be significantly reduced, and the power cost required therefor can be saved.

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Specific embodiments of the present invention will be described below with reference to the accompanying drawings. 1 to 3 are views showing an embodiment of the first invention. In the figure, reference numeral 10 is a first filter medium, and here, a sheet of porous material bent in a pleat shape is arranged in a cylindrical shape.

The above filter medium 10 includes upper and lower end members 12,
An inner wall plate 14 made of a material having air permeability (here, punching metal is used) is provided on the inner peripheral surface thereof to be supported by 11. By providing the end member 12 with the discharge hole 13 for discharging the air from which the solid is separated, the end portion on the end member side is opened.

Reference numeral 20 in the drawing is a second filter medium, which is the first filter medium.
It has the same structure as the filter medium and has a shorter overall length and a smaller diameter. This second filter medium 20 is arranged with one end aligned with the end member 11 side of the first filter medium 10, but before the solid is separated at the position where the end member 11 of the second filter medium 20 is located. By providing the inflow hole 21 for inflowing the air, the end portion on the end member side is opened. Then, the end member 22 is disposed at the other end of the second filter medium 20, so that the end portion on the end member side is closed.

Reference numeral 23 in the drawing denotes an outer wall plate made of a material having air permeability (here punching metal is used), which is provided on the outer peripheral surface of the second filter material in order to maintain strength. .

In the above elements, the air before solids are separated is the outer periphery of the first filter medium 10 and the second filter medium 20.
Is introduced through the inflow hole 21 at one end of the first filter medium, and the solid content is separated by passing through these filter mediums.
From the inner circumference of 0 and the outer circumference of the second filter medium toward the discharge hole 13 at one end of the first filter medium 10 (in the figure, the flow of air before filtration is indicated by a solid arrow, and after filtration, The flow of air is indicated by the dotted arrow.).

FIG. 4 is a diagram showing a different embodiment of the first invention. In this embodiment, the second filter medium 20 is
The diameter is reduced toward the closed end which is the end member 22 side, and since the rest of the configuration is common to the above-described embodiment, its description is omitted.

FIG. 5 is a diagram showing an embodiment of the second invention.
Reference numeral 30 in the drawing is a first filter medium, and here, a sheet of porous material bent in a pleat shape is arranged in a cylindrical shape.

The above-mentioned filter medium 30 includes upper and lower end members 32,
An inner wall plate 34, which is supported by 31, is made of a breathable material (here punching metal is used) to maintain strength. The end member 32 is provided with a discharge hole 33 for discharging the air from which the solid has been separated, so that the end portion on the end member side is opened.

Reference numeral 40 in the drawing is a second filter medium, which is the first filter medium.
It has the same structure as the filter medium and has a shorter overall length and a smaller diameter. The second filter medium 40 is arranged with one end aligned with the end member 31 side of the first filter medium 20, but before the solid is separated at the position where the end portion of the second filter medium 40 is located as the end member 31. By providing the inflow hole 41 for inflowing the air, the end portion on the end member side is opened. Then, the end member 42 is arranged at the other end of the second filter medium 40, so that the end portion on the end member side is closed.

Reference numeral 43 in the drawing denotes an outer wall plate made of a material having air permeability (here punching metal is used), which is provided on the outer peripheral surface of the second filter material in order to maintain strength. .

Reference numeral 50 in the drawing denotes a third filter medium, which is the second filter medium.
It has the same structure and length as the filter medium, and has a smaller diameter than this. The third filter medium 50 is arranged on the end member 31 side of the first filter medium 30 with one end aligned, and the end member 51 is further arranged, whereby the end portion on the end member side is closed. On the other hand, the other end of the third filter medium 50 is arranged on the side of the end member 42 of the second filter medium 40 with one end aligned, and a solid is placed at this end member 42 where the end of the third filter medium 50 is located. By providing the discharge hole 52 for discharging the separated air, the end portion on the end member side is opened.

Reference numeral 53 in the drawing denotes an inner wall plate made of a material having air permeability (here, punching metal is used), which is provided on the inner peripheral surface of the third filter medium in order to maintain strength. is there.

In the above element, the air before the solid is separated is the outer periphery of the first filter medium 30 and the second filter medium 40.
Inflow hole 41 of the third filter medium 5 through this inflow hole 41.
It is introduced from the outer periphery of 0 and the solid content is separated by passing through these filter media. The air from which the solid content has been separated is discharged from the inner periphery of the first filter medium 30 and the outer periphery of the second filter medium 40, and also from the inner periphery of the third filter medium 50.
2 is discharged toward the hole 33 at one end of the first filter medium 30 (in the figure, the air flow before filtration is indicated by a solid arrow, and the air flow after filtration is indicated by a solid arrow). Indicated by dotted arrows.).

[0027]

According to the present invention having the above structure,
Since a plurality of cylindrical filter media are provided within a certain volume,
It is possible to obtain a larger filter medium area while maintaining a constant volume, and a cartridge filter element that is more compact than the prior art with respect to a processable air volume is realized. Therefore, when this is used in a dust collector, the dust collector becomes more compact with respect to the amount of air that can be processed, which contributes to reduction of the cost of the can and power cost.

Further, since a plurality of cylindrical filter media are provided within a fixed volume, the void volume on the outer circumference of the filter media is reduced, and as a result, the amount of high pressure air for backflow cleaning of the element is greatly reduced. This also contributes to the reduction of the power cost required for it.

[Brief description of drawings]

FIG. 1 is a sectional view of a cartridge filter element of the first invention.

FIG. 2 is a sectional view of the same.

FIG. 3 is a perspective view of the same.

FIG. 4 is a sectional view of a different embodiment of the cartridge filter element of the first invention.

FIG. 5 is a sectional view of the cartridge filter element of the second invention.

FIG. 6 is a cross-sectional view of a prior art cartridge filter element.

FIG. 7 is a sectional view of the same.

[Explanation of symbols]

 10 First Filter Material 13 Discharge Hole 20 Second Filter Material 21 Inlet Hole

Claims (4)

[Claims] 1. A structure in which a tubular second filter medium having a shorter overall length and a smaller diameter is arranged inside one end of the tubular first filter medium with one end aligned, and these filter media are arranged at one end with the aligned ends. Is closed at the end of the outer first filter medium and
A cartridge filter element for a dust collector, wherein the end of the filter medium is opened, the end of the first outer filter medium is opened at the other end, and the end of the second inner filter medium is closed. 2. The cartridge filter element for a dust collector according to claim 1, wherein the diameter of the second inner filter medium is reduced toward the closed end. 3. A cylindrical second filter medium having a shorter overall length and a smaller diameter is arranged inside one end of the first cylindrical filter medium with one end aligned, and a cylindrical pipe having a smaller diameter than the second filter medium is arranged inside the second filter medium. The third filter medium is arranged so that one end thereof is aligned, and these filter media are closed at one end where the end portions are aligned, at the end of the outermost first filter medium and the end of the innermost third filter medium. At the same time, the end of the intermediate second filter medium is opened, and the other end of the first outermost first filter medium is opened.
A cartridge filter element for a dust collector, wherein an end of a filter medium and an end of an innermost third filter medium are opened and an end of an intermediate second filter medium is closed. 4. The filter medium is a pleated filter medium.
4. The cartridge filter element for a dust collector according to any one of 1 to 3.