KR20120123173A - Shaped filter - Google Patents

Abstract

PURPOSE: A shaping filter is provided to maintain corrugated shapes against the repeated spraying operation of a pulse jet by reinforcing the folding parts of the corrugated shapes. CONSTITUTION: A shaping filter is composed of a fiber assembly such as needle punch non-woven fabric. Cylindrical filtering fabric is corrugated. The folding parts of the corrugated shape of the filtering fabric are sewed with reinforcing fabric(12) by sewing thread. Sewed parts(16-1, 16-2) and the reinforcing fabric at the sewed parts are extended to the entire length of the corrugated shape of the fabric. The corrugated shape of the filtering fabric is maintained.

Description

Molded Filters {SHAPED FILTER}

The present invention relates to a shaping filter for a dust collector.

In order to increase the collection efficiency in the dust collector, a work is performed in which the filter cloth is composed of a so-called molded filter such as a pleated shape. By foldable structures such as wrinkles, the surface area becomes relatively large, and the dust collection efficiency is increased accordingly. On the other hand, when a filter medium having a low rigidity such as a needle punch nonwoven fabric or a woven fabric is used as the filter cloth, the material is soft and the wrinkle shape cannot be maintained as it is. In the maintenance of the conventional wrinkles, the wrinkles were often immobilized by impregnating a thermosetting resin in the filter medium and molding the wrinkles under heating. Impregnation of the thermosetting resin is disadvantageous in terms of filtration capacity. On the other hand, in order to maintain the pleat shape, a method for sewing the opposing portions of the filter cloth along the lengthwise direction of the filter cloth in close proximity to the fold is already proposed in the folded portion (mount and valley portions) in the pleat shape (patent Documents 1 and 2).

Japanese Patent Laid-Open No. H5-277316 Japanese Patent Publication No. 2009-011989

In the filter cloth which maintains a pleat shape mainly using the sewing of the prior art, when used as a filter cloth (bag filter) for dust collectors, there existed a problem in durability. That is, in the dust collector, a cylindrical shape is hold | maintained by the retainer arrange | positioned in order to hold the cylindrical shape of a filter cloth inside. In addition, in the dust collector, a pulse jet, an air blow, or a dust removal method (including a vibrating method) is repeatedly sprayed from the inside on a regular basis for cleaning the filter cloth. In the case of the structure that secures the wrinkle shape mainly by sewing, since the rigidity of the wrinkle part is weaker than that of the resin processed product, the sewing retainer is folded inside the filter cloth by the jet of pulse jet (valley part in the wrinkle shape). As the dust removal process is repeatedly performed, it is liable to be drooped, and the wrinkles disappear during repeated cleaning, which may lower the filtration efficiency or damage the filter cloth early. In addition, since the folds on the outside of the filter cloth (mountains in the shape of wrinkles) do not directly contact the retainer, damage to the filter cloth does not proceed as quickly as the inside that collides with the retainer in the outer side. There was a fear that deformation due to blow-bye and repeated bending from the thread strands caused, or in the worst case, damage due to fatigue.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems, and is a dust removing process such as a repetitive pulse jet for cleaning in a dust collecting device molding filter (bag filter) which is not mainly based on resin processing and maintains a pleat shape by sewing. Regardless, the object is to maintain the wrinkle shape for a long time and to prevent premature damage of the fold.

In the shaping | molding filter for dust collectors of this invention, the opposing part of a filter cloth is sewn to at least one part of a fold | segment in order to hold | maintain a wrinkle shape, and sewing attachment is carried out in the fold part of at least one part of the fold | folded parts which are sewn-attached. It is carried out in the state of. The reinforcing cloth extends over substantially the entire length of the corrugated portion in the longitudinal direction, and is preferably integrated by sewing together. In addition, a reinforcement cloth can be made into the whole or part of the folded part in the inner side (retainer close side) of a filter cloth. The reinforcement cloth can also be applied to all or part of the folds on the outer side (side away from the retainer) of the filter cloth. In some cases, the reinforcement cloth may be applied only to the fold at the outer side of the filter cloth (away from the retainer).

Sewing of the opposing portions at the pleated folds is made by sewing the reinforcement cloth of the folds together, thereby strengthening the pleated folds and maintaining the pleated shape against repeated jet jet spraying for cleaning. ) And life extension can be realized. In addition, it is possible to effectively protect the pleat shape against the impact shock caused by the injection of the pulse jet by damaging the whole or part of the folded portion inside the filter cloth.

BRIEF DESCRIPTION OF THE DRAWINGS It is a longitudinal cross-sectional view which shows typically the filter cloth structure of the shaping | molding filter which concerns on one Embodiment of this invention in the expanded state.
It is a figure which shows typically the cylindrical shape of the filter cloth of FIG.
3 is a side view of the filter cloth formed in a tubular shape.
4 is a cross-sectional view along the line IV-IV of FIG. 3.
It is a schematic perspective view explaining the process of edge part of the filter cloth which concerns on sewing.
6 is a cross-sectional view showing an inlet formed by embedding a snap ring.
It is a longitudinal cross-sectional view which shows typically the filter cloth structure of the shaping | molding filter which concerns on other embodiment of this invention in the expanded state.
FIG. 8 is a schematic cross-sectional view of the shaping filter of FIG. 7.
It is a longitudinal cross-sectional view which shows typically the filter cloth structure of the shaping | molding filter which concerns on another embodiment of this invention in the expanded state.
It is a longitudinal cross-sectional view which shows typically the filter cloth structure of the shaping | molding filter which concerns on other embodiment of this invention in the expanded state.
Fig. 11 is a side view showing the completed state of a filter having an inlet and a bottom part by sewing, by breaking a portion of the inlet;

In Fig. 1, reference numeral 10 denotes a filter cloth in the molding filter of the present invention, and the filter cloth 10 is a needle punch nonwoven fabric in this embodiment, and organic synthetic fibers such as polyester, nylon, and acrylic Short fibers (staples) of organic synthetic fibers such as polyester, nylon, and acrylic can be formed by needle punching on a base fabric as a woven fabric made of a line of thread of fibers or long fibers. . Instead of the nonwoven fabric, it is also possible to constitute a woven fabric having good dust collecting property. In addition, the filter cloth 10 is not limited to organic synthetic fibers and may be configured to include inorganic fibers such as ceramics. The filter cloth 10 is formed in a pleated shape as shown in Figs. 1 and 2 as it passes through the pleating machine. In this embodiment, the filter cloth is formed in a cylindrical shape as shown in FIG. 2. The folds (folds 10-1 and valleys 10-2) in the corrugation shape extend in a direction parallel to the centerline, and are closed at one end (bottom) and opened at the top by means described below. It becomes a shape, it introduces from the outer side (outer peripheral side) like arrow a, and has a structure discharged from an inner side (inner peripheral side) like arrow b. Therefore, the filtration layer in the filter cloth 10 is located in the outer peripheral surface of the cylindrical body of FIG. 2, and the base fabric in the filter cloth 10 is located in the inner peripheral surface of the cylindrical body. That is, the process fluid first comes into contact with the outer filtration layer in the filter cloth 10 such that dust in the process fluid is retained by the filtration layer.

According to the present invention, the maintenance of the pleat shape of the filter cloth 10 does not basically depend on the resin processing which is conventionally employed due to the nonwoven fabric lacking rigidity (resin processing is not necessary, even if not necessary at least), The holding of the wrinkles is performed by the sewing structure. That is, since the nonwoven fabric cannot maintain the wrinkle shape alone due to its low rigidity, conventionally, the nonwoven fabric is impregnated with a thermosetting resin in the nonwoven fabric, and the nonwoven fabric is passed through the creasing machine in the state impregnated with the thermosetting resin. At this time, the filter cloth was heated to the thermosetting temperature of the resin to fix the wrinkles. In the present invention, the sewing structure is taken to maintain the wrinkle shape without basically relying on the resin processing (or at the minimum amount of resin). Referring to the maintenance of the wrinkle shape by the sewing structure, in Fig. 1, 16-1, 16-2 denotes a sewing line for maintaining the wrinkle shape, the sewing lines 16-1, 16-2 are The opposing part of the filter cloth 10 is sewn (sewed) in close proximity to the corrugated peak portion 10-1 and the valley portion 10-2. That is, 3 to 10 mm, preferably 5 to 5 mm from the top or bottom of the portion near the hill 10-1 or the valley 10-2, such as the hill 10-1 or the valley 10-2. At the distance of 6 mm, the opposing layer of the filter cloth 10 is sewn by 8-60th sewing thread (19-20 sewing thread in the case of polyester cloth). The sewing lines 16-1 and 16-2 extend over substantially the entire length of the pleated portion of the filter cloth as shown in Fig. 2, thereby making it possible to maintain the pleated shape.

In the embodiment shown in FIG. 1, all the folded portions (curved portions 10-2) of the inner side (retainer arrangement side described later) in the tubular shape of the filter cloth are reinforced from the outer side (outer side) to the folded portion. The gun 12 is touched. The reinforcement cloth 12 extends substantially along the entire length of the cylindrical filter cloth 10, and the inner sewing line 16-2 for retaining the pleat shape by sewing also includes the reinforcement cloth 12. It is made to sew. That is, although the reinforcement cloth 12 is not shown in FIG. 2 for simplicity, in the present embodiment, the sewing line 16-2 is applied to the valley portion 10-2 from the outer side (outer side) at substantially the entire length. It is sewn together by. The reinforcing cloth 12 may be the same cloth, but can be made into a cloth having a smaller basis weight made of the same kind of fibers. The arrangement of the reinforcement cloth 12 in the whole cross section of the filter cloth 10 is shown in FIG. 4, and in this embodiment, the reinforcement cloth 12 is located in an inner side (retainer 14 side). 11 shows the filter cloth 10 in a state arranged in the cell of the dust collector, and a retainer 14 for holding the tubular shape of the filter cloth 10 is inserted into the inside (cylindrical inner circumferential side) of the filter cloth 10. Is placed. The retainer 14 may be a well-known type of basket shape or may be formed by forming a punching plate in a cylindrical shape. FIG. 1 is a diagram schematically showing an enlarged positional relationship between the fold-shaped folded portion 12 and the retainer 14 on the inner side of each other by sewing the reinforcement cloth 12 together.

In the embodiment of Fig. 1, a reinforcing cloth is not applied to the folded portion (mountain 10-1) on the outer side of the corrugation shape (side from the retainer described later), but as shown by the imaginary line 12 '. A reinforcing cloth 12 'may also be applied to the outer folded portion (mountain 10-1) to sew together along the sewing line 16-1 for the outer wrinkle shape, thereby obtaining a more firm wrinkle shape. There is a number.

The reinforcement cloth 12 is basically made of the same material as the used filter cloth 10. If the filter cloth 10 is polyester, the reinforcement cloth 12 also becomes a polyester material. When the filter cloth 10 is a polyester nonwoven fabric, the reinforcement cloth 12, 12 'can be made into a polyester woven fabric. The basis weight (weight per unit area) may be smaller than the filter cloth 10. When the filter cloth 10 is a woven fabric, the reinforcement cloth 12 can be made into the same cloth.

Next, the structure for attaching to the cell plate of the dust collector is formed in a bag shape from the cylindrical filter cloth in which the pleat shape is fixed by sewing as described above. FIGS. 3 and 4 are pleat by sewing. The filter cloth fixed in shape is formed in a cylindrical shape. That is, the filter cloth in which the pleat shape is fixed by sewing is rolled into a cylindrical shape, and is formed in a cylindrical shape by sewing along a longitudinal seam. In addition, about both upper and lower ends of a cylindrical shape, wrinkles are crushed in the upper and lower edge parts 10-1 of the cylindrical filter cloth 10 as shown in FIG. The end portion 10-1 in which the diameter of the filter cloth after flattening by sewing is reduced is also shown in FIG. Then, a separate non-filter cloth of cylindrical shape is inserted into the lower end of the filter cloth 10 having the inlet, and the reinforcing cloth 18 is sewn into a bag shape, and the upper end is a snap ring or rope to be suitable for the dust collector. Is put in appropriately and sewed to become an inlet. In Fig. 3, reference numeral 18 denotes a circular reinforcement cloth, and the reinforcement cloth 18 abuts the flattened lower end portion 10-1 of the filter cloth 10 which is the bottom of the filter, and the outer peripheral portion of the reinforcement cloth 18 Folded with respect to the upper surface of the filter cloth 10 of the shape, the folded portion (18A, 11) of the reinforcing cloth (18) is sewn to the filter cloth 10, in Fig. 11 the reference numeral L2 by sewing The sewing portion is shown, whereby a closed bottom of the shaped filter of the sewing structure is obtained. In addition, the sewing part used as the inlet of a shaping | molding filter is typically shown by FIG. 6, and 22 is a metallic snap ring, Comprising: It forms with the strip | belt piece of an elastic steel material. The snap ring 22 is surrounded by the inlet fabric 24 and the snap ring 22 is driven into the inlet fabric 24 as the inlet fabric 24 is sewn at both ends (sewing attachment line). Represented by L3). In this way, the inlet fabric 24 which sewed the snap ring 22 is attached to the end (the upper end of FIG. 11) which becomes the inlet of the filter cloth 10, and is sewn (seam line is indicated by L4).

In order to obtain a predetermined length, the filter cloth 10 may arrange | position a plurality of cylindrical shape in the vertical direction, and may comprise a lengthwise length by connecting adjacent stages by sewing.

Fig. 7 shows another embodiment, in which the reinforcement cloth 12 is placed only on the valley portion 10-2 (folding portion on the inner circumference side in the tubular shape) and on the hill portion 10-1 (folding portion on the outer circumference side). Not shown is the same as in Fig. 1, but is appropriately intermittently instead of all of the valleys 10-2 (see Fig. 8). The intermittent degree depends on the conditions of use. That is, since the filter cloth is often exchanged regularly in the dust collector, it is possible to obtain a balance between cost and filtration performance by using a minimum reinforcement cloth 12 capable of maintaining a pleat shape within a period of use.

FIG. 9 shows another embodiment, in which the reinforcement cloth 12 is wrinkled by the sewing line 16-2 against the ridge 10-2 (folded portion of the inner circumference) only (in whole or in part). Although it is the same to reinforce shape, sewing of the opposing part is not made in the mountain part 10-1 (folding part of outer periphery). Depending on the use situation, even in such a structure, the reinforcing effect of the reinforcing cloth 12 can maintain the desired wrinkle shape within the use period.

Fig. 10 shows another embodiment, in which the present embodiment is not subjected to strong load on the folded portion (curved portion 10-2) of the inner circumference (the retainer 14 side) during pulsing in the cleaning. As a case, the reinforcement cloth 12 'is partially (or entirely) applied only to the fold part (mountain part 10-1) of the outer periphery (side away from the retainer 14), and together in the sewing line 16-1. It is sewn. The inner folded portion (the valley portion 10-2) is not made of sewing, but sewing of the opposite portion can be performed by sewing lines such as the sewing line 16-2 of FIG.

The attachment to the dust collector and the like of the filter configured in this way is as well known. That is, in FIG. 11, reference numeral 26 denotes a cell plate of the dust collector, a filter is inserted into a plurality of openings 28 formed in the cell plate 26, and the snap ring 22 uses grooves on the surface of the opening 28. Is fitted. Then, the retainer 14 for retaining the shape of the filter operating from the inside of the filter is inserted as indicated by the imaginary line.

Even when the filter cloth 10 according to the embodiment of FIG. 1 is used, the folds of the filter cloth 10 (curved portion 10-2) of the filter cloth 10 on the retainer side (inner side) (if necessary, the wrinkles of the filter cloth on the outside side). The reinforcement cloth 12 and the reinforcement cloth 12 'are applied to the mountain portion 10-1, and also the sewing line 16-2 for the wrinkle shape. When the reinforcing cloth 12 'is applied to the mountain portion 10-1, it is sewn together by the sewing line 16-1). There is a number. In addition, when spraying a repetitive pulse, the spring may be mounted on the lower end of the filter cloth to increase the tension of the filter cloth. In the present invention, the strength in the tension direction is high due to the installation of the reinforcement cloths 12 and 12 '. It is suitable for such a repetitive pulse application method.

10: filter cloth
10-1, 10-2: folded part
12,12 ': reinforcement
14: retainer
16-1, 16-2: Sewing Line
22: snap ring
24: entrance cloth

Claims (4)

The cell plate of the dust collector is provided with a cylindrical filter cloth disposed inside and disposed outside thereof, and the filter cloth is a molded filter forming a pleated shape, and is formed on at least a part of the pleated folded portion to maintain the pleated shape. And the opposing portion of the filter cloth is sewn together, and at least a part of the folded portion of the opposing sewing cloth is sewn with the opposing portion of the filter cloth for maintaining the pleat shape in a state where a reinforcing cloth is attached to the folded portion. filter. The method of claim 1,
And the sewing attachment portion extends over substantially the entire length of the longitudinal direction along the pleats of the filter cloth, and wherein the reinforcement bag facing the fold portion extends along the substantially entire length of the longitudinal direction. The method of claim 2,
A molded filter in which each folded portion close to the retainer is provided with a reinforcing cloth, and sewing is performed on the opposite side of the filter cloth for maintaining the pleat shape. The method of claim 2,
A molded filter in which the folded portion near the retainer is spaced apart in the circumferential direction with appropriate reinforcement cloth, and sewing is performed on the opposite side of the filter cloth for maintaining the pleat shape.

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