BR112019014105B1 - DUST COLLECTOR, AND, DUST REMOVAL METHOD - Google Patents

Abstract

The purpose of the present invention is to provide: a dust collection device comprising an air jet type dust removal mechanism capable of removing dust uniformly from the entire length of a cylindrical filter without increasing the pressure loss of the cylindrical filter; and a dust removal method for such a dust collection device. This dust collection device 100 is provided with an air jet type dust removal mechanism for removing dust adhering to a cylindrical filter 10. The air jet type dust removal mechanism is provided with: a first section of discharging with a first discharge nozzle 24 for discharging a jet of air from an opening in an end side of the cylindrical filter towards the interior of the cylindrical filter; and a second discharge section with a second nozzle 32 for discharging a jet of air from the other end side of the cylindrical filter toward the opening of the one end side of the cylindrical filter. The second discharge nozzle is provided at the front end side of a conduit extending from the one side of (...).

Description

Technical field

[001] The present invention relates to a dust collector and a dust removal method therefor, and more specifically relates to a dust collector including an air jet type dust removal mechanism for removing dust adhering to a cylindrical filter, and a method of removing dust from a filter in such a dust collector.

Fundamentals of the technique

[002] As a dust collector that removes dust from a dust-containing gas by a filter, a dust collector including an air jet type dust removal mechanism for ejecting compressed air from a discharge section in a pulsed state in order to remove dust adhered to a filter is known.

[003] For example, a dust collector is known including a dust removal mechanism for increasing the internal pressure of a filter to equalize the internal pressure throughout the length of the filter, providing a tapered tube with a frustoconical shape in the cylindrical filter. or providing a concave bottom plate at a lower end (e.g., refer to Patent Document 1).

Prior art document Patent document

[004] Patent document 1: Unexamined Japanese Patent No. 2011-245439

Summary of the Invention Problem to be solved by the invention

[005] However, in the above dust removal mechanism, an effect of evenly removing dust along the entire length of a cylindrical filter is still insufficient. Additionally, a member which obstructs an air flow is installed in the cylindrical filter, and therefore there is a problem that the pressure loss of the filter is increased.

[006] The present invention has been made in view of such points and an object of the present invention is to provide: a dust collector that includes an air jet type dust removal mechanism capable of removing dust uniformly from the entire length of a cylindrical filter without increasing the pressure loss of the cylindrical filter; and a dust removal method for such a dust collector.

Ways to solve the problem

[007] In accordance with the present invention, there is provided a dust collector that includes an air jet type dust removal mechanism for removing dust adhering to a cylindrical filter, the air jet type dust removal mechanism comprising : a first discharge section as a first discharge nozzle for discharging a jet of air from an opening in a first end side of the cylindrical filter towards the interior of the cylindrical filter; and a second discharge section with a second discharge nozzle for discharging a jet of air from a second end side of the cylindrical filter toward the opening of the first end side of the cylindrical filter, and the second discharge nozzle toward the discharge is provided on an end side of a pipeline extending from the first end side of the cylindrical filter to the second end side of the cylindrical filter.

[008] According to such a configuration, any member that increases the filter pressure loss of the inner space of the cylindrical filter is not arranged, and additionally, opposing air jets are discharged from both end sides of the cylindrical filter in towards the inner space of the cylindrical filter, and therefore dust can be removed uniformly along the entire length of the cylindrical filter without increasing the pressure loss in the cylindrical filter.

[009] Additionally, the air jet discharge nozzles for dust removal can be arranged in opposite positions on the filter without adding any significant change to an existing dust collector.

[0010] According to another preferred aspect of the present invention, the pipeline has an inverted path provided at a tip portion, and the second discharge nozzle is provided at one end of the inverted path.

[0011] According to such a configuration, the air jet discharge nozzles for dust removal can be arranged in opposite positions on the filter in a simple configuration.

[0012] According to another preferred aspect of the present invention, the inverted path has a substantial U-shape.

[0013] According to another preferred aspect of the present invention, the tubing is arranged in an internal space of the cylindrical filter, which is a space into which clean air is introduced.

[0014] In a configuration in which the tubing is arranged outside the cylindrical filter where dust exists, there is a possibility that dust will enter the tubing in that portion and be ejected from the end of the tubing into the filter. Therefore, in the configuration where the piping is arranged outside the cylindrical filter, it is necessary to ensure the air tightness of the piping, and the manufacturing cost of the device is increased. However, according to the above configuration, the pipeline is arranged in the internal space of the cylindrical filter, which is the space into which clean air is introduced, and therefore high air tightness of the pipeline itself is not required, and the manufacturing cost of collector and the like is reduced.

[0015] According to another preferred aspect of the present invention, the pipeline is arranged outside the cylindrical filter, and the reverse path penetrates the filter on the second end side of the cylindrical filter to extend into an internal space of the cylindrical filter.

[0016] According to such a configuration, any member that obstructs the air flow does not exist inside the cylindrical filter, and therefore, the air flow becomes smooth in the internal space of the filter.

[0017] According to another preferred aspect of the present invention, the second spout has a tapered shape.

[0018] According to such a configuration, pressure and velocity of the discharged air jet are increased by the tapered discharge nozzle. As a result, the faster air blast reaches a farther area and additionally the faster air stream absorbs more surrounding air, so that dust removal will be effectively improved.

[0019] According to another preferred aspect of the present invention, the second discharge nozzle has an expanded shape.

[0020] According to such a configuration, the discharged air jet is expanded by the expanded shape of the nozzle, and a dust removal effect can be obtained over a wider area of the interior of the filter.

[0021] According to another preferred aspect of the present invention, a tip side of the inverted path is branched into a plurality of portions, and a second discharge nozzle is provided in each of the portions.

[0022] According to such a configuration, particularly, when the internal cross-sectional area of the cylindrical filter is large, a dust removal effect can be obtained over a wider area of the filter by discharging the air jets from the plurality of portions.

[0023] According to another preferred aspect of the present invention, the second discharge section is configured integrally with the cylindrical filter and is configured to be integrally detachable from the dust collector.

[0024] According to such an arrangement, the filter can be unpinned without further operation, and it is possible to easily unpin the filter similarly to a conventional manner.

[0025] According to another preferred aspect of the present invention, the dust collector including: a cell plate divided into a dust chamber and a clean air chamber; and a filter frame for mounting the cylindrical filter to the cell plate, wherein the filter frame has a protuberance complementary to a hole formed in the first end side of the cylindrical filter, and the cylindrical filter is detachably mounted to the dust collector by fitting the protrusion into the hole.

[0026] According to such a configuration, the positioning of the discharge positions of the air jets and the center position of the filter is carried out reliably and easily, and an effective dust removal effect by the air jets can be obtained .

[0027] A dust removal method is provided for any of the above dust collectors, the dust removal method including: an air jet discharge step from the first discharge section and the second discharge section to remove cylindrical filter dust, in which the air jet discharge of the first discharge section and the air jet discharge of the second discharge section are started with a time difference.

[0028] According to such a configuration, the portion of pressure rise generated by collision of the two air jets can be changed, and therefore, the dust in a specific portion of the filter can be reliably removed.

[0029] According to another preferred aspect of the present invention, the removal step is carried out while the time difference is changed.

[0030] According to such a configuration, the pressure raising portion is sequentially moved in the filter, and dust from the entire filter can be effectively removed.

Effects of the Invention

[0031] According to the present invention, a dust collector is provided that includes an air jet type dust removal mechanism capable of uniformly removing dust from the entire length of the cylindrical filter without increasing the pressure loss in the cylindrical filter ; and a dust removal method for such a dust removal device.

Brief description of the drawings

[0032] Figure 1 is a schematically cross-sectional view illustrating a configuration of a dust collector including an air blast type dust removal mechanism of a preferred embodiment of the present invention.

[0033] Figure 2 is a plan view of a filter frame of the dust collector shown in Figure 1.

[0034] Figure 3 is a cross-sectional view along line III-III in figure 2.

[0035] Figure 4 is a plan view of an upper filter plate of the dust collector of Figure 1.

[0036] Figure 5 is a schematically transversal longitudinal view illustrating a proximity configuration of the dust collector filter of Figure 1.

[0037] Figure 6 is a schematic diagram illustrating a modification of the dust removal mechanism.

[0038] Figure 7 is a schematic diagram illustrating a modification of the dust removal mechanism.

[0039] Figure 8 is a schematic diagram illustrating a modification of the dust removal mechanism.

[0040] Figure 9 is a plan view of the modification of Figure 8.

[0041] Figure 10 is a schematic diagram illustrating a modification of the dust removal mechanism.

[0042] Figure 11 is a schematic diagram illustrating a modification of the dust removal mechanism.

Description of preferred modalities

[0043] Hereinafter, a dust collector of a first embodiment of the present invention will be described with reference to the drawings. The dust collector of this embodiment is a dust collector that includes an air jet type dust removal mechanism to remove dust adhering to a cylindrical filter.

[0044] Figure 1 is a schematically cross-sectional view illustrating a configuration of a dust collector 100 including an air jet type dust removal mechanism of this embodiment.

[0045] As illustrated in Figure 1, the dust collector 100 includes a housing 1. An internal space of the housing 1 is divided or partitioned into a dust chamber 4, into which dust-containing air is introduced, and a clean air 6, to which clean air obtained by removing dust is introduced, by a cell plate 2 serving as partition plate.

[0046] A plurality (three in this embodiment) of cylindrical filters 10 having a bottom portion is mounted on the cell plate 2, serving as a partition plate, by means of a filter frame 8. In this embodiment, the filter 10 has a pleated shape and is a structure in which dust is filtered by an outer surface of the filter cloth (cloth) and is captured. However, the present invention is not limited to the filter having this structure, and a filter having another structure, for example using cylindrical filter cloth, can be used.

[0047] Figure 2 is a plan view of the filter frame 8, and Figure 3 is a cross-sectional view along line III-III in Figure 2. Figure 4 is a plan view of each cylindrical filter 10.

[0048] As illustrated in Figure 2, a circular opening 8a suitably sized to the outer diameter of the cylindrical filter 10 is formed in the filter frame 8. Protuberances 16 are formed on an outer edge of each of the openings 8a of the filter frame 8 in predetermined angles (120 degrees in this mode).

[0049] As illustrated in Figure 4, each of the cylindrical filters 10 includes a top filter plate 12 at one end. The upper filter plate 12 is an annular frame member made of plastic, metal or the like, and is provided with attachment holes 14 complementary to the protrusions 16 of the filter frame 8 at predetermined angles (120 degrees in this embodiment).

[0050] In this embodiment, the upper filter sheets 12 are arranged so that the upper filter sheet 12 aligns with the openings of the filter frame 8, and the protuberances 16 on the outer edges of the openings 8a of the filter frame 8 are fitted into the holes 14 of the upper filter plate 12, so that the cylindrical filter 10 is mounted on the filter frame 8.

[0051] In this embodiment, the filter frame 8 assembled with the cylindrical filter 10 is fitted into a filter frame mounting member (not shown) provided on the cell plate 2, so that the cylindrical filter 10 is mounted on the cell plate 2 through filter frame 8.

[0052] With such a configuration, air containing dust on the side of the dust chamber 4 flows into the clean air chamber 6 through the filter 10.

[0053] The dust collector 100 of this embodiment includes an air jet type dust removal mechanism for removing dust adhering to the cylindrical filters 10. This air jet type dust removal mechanism includes a first discharge section 18 and a second discharge section 20.

[0054] The first discharge section 18 is configured to discharge air jets from first end openings of the cylindrical filter 10 towards the interior of the cylindrical filter. More specifically, the first discharge section 18 is disposed at an upper position of the cell plate 2 and includes a manifold 22 disposed substantially parallel to the cell plate 2, and a plurality of first discharge nozzles 24 formed in that manifold 22.

[0055] The first discharge nozzle 24 is arranged on the first side of the cylindrical filter 10 (filter upper plate side, i.e. the filter frame side) so that the discharge hole is directed towards the interior of the cylindrical filter 10 on the central axis of the cylindrical filter 10, and is configured to discharge compressed air supplied through the distributor 22 as air jets from the side opening of the first end of the cylindrical filter 10 towards the interior of the cylindrical filter 10.

[0056] At a base end of the distributor 22, a first air tank 26 and a first solenoid valve 28 having an air valve are provided. The first discharge section 18 is configured so that compressed air is supplied to the first discharge nozzles 24 through the distributor 22 by the first air tank 26 and the first solenoid valve 28.

[0057] On the other hand, the second discharge section 20 is configured to discharge air jets from the second end of the cylindrical filter 10 towards the first side openings at the end of the cylindrical filter 10. More specifically, the second discharge section 20 includes pipes 30, each extending from the first end to the second end in an internal space of the cylindrical filter 10, and second discharge spout 32 provided at the end of the pipe 30. Each pipe 30 has an inverted path substantially shaped in U 30a at the end portion (second end side), and is provided with a second discharge spout 32 at one end of the inverted path 30a.

[0058] In this embodiment, as illustrated in Figure 5, the inverted path 30a each has a substantially U-shape that reverses when drawing a curved line, i.e. during the curve. Each tubing 30 is substantially J-shaped as a whole by this substantially U-shaped inverted path 30a at the nose end.

[0059] The pipes 30 are arranged to extend along (in contact with) the inner circumferential surface of the cylindrical filter 10, and the second discharge nozzle 32 are configured so that the discharge orifice at the ends is located in the center (on the central axis) of the cylindrical filter 10 and opens towards the side opening of the first end of the cylindrical filter 10.

[0060] Therefore, in this embodiment, the discharge orifice of the first discharge nozzle 24 and the discharge orifice of the second discharge nozzle 32 are arranged to face each other on the central axis of the cylindrical filter 10.

[0061] The upper end of the pipe 30 is directly connected to a distributor 34 provided with a second solenoid valve 36 having an air valve, and are communicated with a second air tank 38.

[0062] The upper end of the pipe 30 may not be directly connected to the manifold 34, and may be arranged in a state separated by about several millimeters, or it may be connected to the manifold 34 using any joint member.

[0063] In this embodiment, the second discharge nozzle 32 is integrally formed with the tubing 30. However, the second discharge nozzle 32 can be formed as separate detachable members of the tubing 30.

[0064] As described above, in this embodiment, the outlet of the first spout 24 and the outlet of the second spout 32 are arranged so as to face each other on the central axis of the cylindrical filter 10, and therefore, air jets from the first upper discharge nozzle 24, and air jets from the second lower discharge nozzle 32 are obliged to directly collide with each other, so that it is possible to efficiently increase the pressure of the internal spaces of the cylindrical filter 10.

[0065] In this embodiment, the pipe 30 is arranged in the internal spaces of the cylindrical filter 10 in a state of being in contact with the internal surface of the cylindrical filter 10. More specifically, protrusions are provided at the upper and lower ends of the pipe 30, holes or recesses complementary to the protrusions on the side of the pipe are provided on the cylindrical filter 10, and the protrusions of the pipe 30 are fitted into the holes or the like on the sides of the filter, so that the pipe 30 is connected to the cylindrical filter 10.

[0066] However, the tubing 30 can be fixed to the internal space of the cylindrical filter 10, so as to extend in contact with the circumferential internal surface of the cylindrical filter 10, using another fastening member.

[0067] Thus, the tubing 30 is positioned so as to extend in contact with the circumferential inner surface of the cylindrical filter 10, so that the tubing 30 is unlikely to become an obstacle to the air jet from the first nozzle. upper discharge nozzle 24, and the air jet from the second lower discharge nozzle 32.

[0068] The pipe 30 can have a structure to be integrally configured with the cylindrical filter 10 and integrally detachable from the dust collector. According to such a configuration, it is possible to easily carry out maintenance operation such as filter replacement similar to the conventional operation in one operation such as replacing the cylindrical filter 10.

[0069] In the dust collector thus configured, similarly to a conventional dust collector, the dust-containing air supplied to the dust chamber 4 is drawn into the clean air chamber 6 through the cylindrical filter 10, and at this time the dust is collected by the cylindrical filter 10.

[0070] As the dust collection operation is carried out, the dust is gradually adhered to the outer surface (side surface of the dust chamber) of the cylindrical filter 10, and the differential pressure between the front and rear of the cylindrical filter 10 increased. When this differential pressure reaches or exceeds the predetermined value, or when the operating time exceeds the predetermined time independent of the differential pressure, the work of removing dust begins.

[0071] In this work of removing dust, the first and second solenoid valves 28, 36 are opened during a predetermined period of time, and compressed air is discharged in the form of air jets from the first and second discharge nozzles 24, 32 serving as air jet discharge sections in the upper outer position of the cylindrical filter 10, and in the inner position of the cylindrical filters 10 facing oppositely to the upper outer part.

[0072] The oppositely discharged compressed air stream impinges on the internal spaces of the cylindrical filter 10, and the internal pressure of each cylindrical filter 10 increases, and dust can be removed evenly along the entire length of the cylindrical filter 10.

[0073] In this embodiment, any member that obstructs the flow of air is not arranged in the internal spaces of the cylindrical filter 10 and, therefore, the pressure of the compressed air is not reduced by such member.

[0074] The start of opening of the first and second solenoid valves 28, 36 can be at the same time, but a time difference between the start times can be provided, that is, the start time of ejection of compressed air from of the first discharge nozzle 24 and the moment of starting ejection of compressed air from the second discharge nozzle 32 can be coordinated.

[0075] Additionally, the time difference between the starting moments of ejection of compressed air from the two discharge nozzles is changed, so that the collision position of the compressed air from the two discharge nozzles, that is, the position of a local point of internal pressure rise can be changed in the longitudinal direction of the cylindrical filter.

[0076] Therefore, a delay between the start times of compressed air ejection from the two discharge nozzles is controlled so that an internal pressure rise point is located close to a portion necessary for removing dust from each filter , so that it is possible to implement proper dust removal according to a filter dust adhesion state.

[0077] When gradually employing a method to change a time difference between the starting moments of compressed air ejection from the two discharge nozzles for a single or a plurality of air jet shots, dust removal can be uniformly performed along all internal surfaces of the cylindrical filter 10 while continuously moving the internal pressure rise point.

[0078] More specifically, a cartridge filter is used, each having a length of 540 mm as the cylindrical filter 10, and a delay between the upper and lower jet start times is sequentially changed in the order of 150 ms, 50 ms , 0 ms (no delay), -50 ms, -100 ms, and - 150 ms, so that it is possible to effectively remove dust from the entire inner circumferential surface of the filter.

[0079] As described above, according to the above embodiment, a mass of compressed air discharged from the first discharge nozzle 24, in the external position of the cylindrical filter 10, and a mass of compressed air discharged from the second discharge nozzle 32, arranged in the internal position of the confronting filter, they are impinged within the cylindrical filter 10, and the dust can be uniformly removed along the entire length of the cylindrical filter 10.

[0080] The present invention is not limited to the above embodiment of the present invention, and various changes and modifications can be carried out within the scope of the technical ideas described in the claims.

[0081] In the above embodiment, the inverted path 30a of the pipe 30 of the second discharge section 20 has substantially U-shaped shapes when drawing the curved line, that is, during the curve. However, as long as the discharge orifice of the second discharge nozzle 32 provided at the tip is open towards the first end of the cylindrical filter 10, the inverted path can have any configurations.

[0082] For example, as illustrated in Figure 6, each inverted path 40a can be used having a shape obtained by linearly inverting a path 40 into an upwardly open “channel shape”. A second discharge nozzle 42 is provided at one end of such an inverted path 40a, so that a discharge orifice is opened in a direction opposite to the first end of the cylindrical filter 10.

[0083] As illustrated in Figure 7, each inverted path 50a having an inverted T-shape branched into two right and left portions can be used at one end of a path 50. The second discharge nozzle 52 is provided at one end of the portions branches from such an inverted path 50a, so that a discharge orifice is opened in the opposite direction to a first end of a cylindrical filter 10.

[0084] In the above embodiment, the tubing 30 is arranged in the internal space of the cylindrical filter 10. However, the present invention is not limited to this arrangement. For example, as illustrated in Figure 8, each tubing 60 may be arranged outside a cylindrical filter 10 so as to extend from one side of the first end to one side of the second end of the cylindrical filter 10. An inverted path 60a of the tubing is extends to penetrate a bottom wall of the cylindrical filter 10, is arranged such that a tip of the inverted path 60a is located in a center of an internal space of the cylindrical filter 10, and is provided with a second discharge nozzle 62 at the tip of the inverted path 60a. As illustrated in Figure 9, an upper end of the tubing 60 is supported by an upper filter plate 12 disposed at one end of the cylindrical filter 10.

[0085] In the above embodiment, the tip of the second discharge nozzle has the same diameter as the pipe. However, as in the configurations of Figure 10 and Figure 11, the second discharge nozzles 72, 82 at the end of the inverted path of the paths 70, 80 may have a tapered shape or an expanded shape.

[0086] In these embodiments, the air pulse discharge section is provided at the upper and lower end of each circular cylindrical filter. However, the shape of the filter is not limited to the circular cylindrical shape. For example, a cylindrical filter having a thin square cross-section and having a closed lower end (a so-called flat plate filter) can be used.

Description of reference numerals

[0087] 100 dust collector 1 housing 2 cell plate 4 dust chamber 6 clean air chamber 8 filter frame 10 cylindrical filter 12 upper filter plate 14 hole 16 projection 18 first discharge section 20 second discharge section 22 distributor 24 first discharge nozzle 26 first air tank 28 first solenoid valve 30 piping 30a inverted path 32 second discharge nozzle 34 distributor 36 first solenoid valve 38 second air tank

Claims (10)

1. Dust collector (100), comprising an air jet type dust removal mechanism for removing dust adhered to a cylindrical filter (10), the air jet type dust removal mechanism comprising: a first section of discharge (18) as a first discharge nozzle (24) for discharging a jet of air from an opening in a first end side of the cylindrical filter (10) towards the interior of the cylindrical filter (10); and a second discharge section (20) with a second discharge nozzle (32) for discharging a jet of air from a second end side of the cylindrical filter (10) towards the opening of the first end side of the cylindrical filter (10), and the second discharge nozzle (32) for discharge is provided on an end side of a pipe (30) extending from the first end side of the cylindrical filter (10) to the second end side of end of the cylindrical filter (10), characterized by the fact that the piping (30) is arranged in an internal space of the cylindrical filter (10), which is a space into which clean air is introduced. 2. Dust collector (100) according to claim 1, characterized by the fact that the pipe (30) has an inverted path (30a) provided in a tip part, and the second discharge nozzle (32) is provided at one end of the inverted path (30a). 3. Dust collector according to claim 2, characterized by the fact that the inverted path (30a) has a U-shape. 4. Dust collector (100) according to any one of claims 1 to 3, characterized in that the second discharge nozzle (32) has a tapered shape. 5. Dust collector (100) according to any one of claims 1 to 3, characterized in that the second discharge nozzle (32) has an expanded shape. 6. Dust collector (100) according to any one of claims 1 to 5, characterized in that a tip side of the inverted path is branched into a plurality of portions, and a second discharge nozzle (32) is provided in each portion. 7. Dust collector (100) according to any one of claims 1 to 6, characterized in that the second discharge section (20) is configured integrally with the cylindrical filter (10) and is configured to be integrally detachable from the dust collector (100). 8. Dust collector (100) according to any one of claims 1 to 7, characterized in that it comprises: a cell plate (2) divided into a dust chamber (4) and a clean air chamber (6 ); and a filter frame (8) for mounting the cylindrical filter (10) to the cell plate (2), wherein the filter frame (8) has a protuberance complementary to a hole formed in the first end side of the cylindrical filter (10), and the cylindrical filter (10) is detachably mounted on the dust collector (100) by fitting the protuberance into the hole. 9. Dust removal method for the dust collector as defined in any one of claims 1 to 8, the dust removal method characterized in that it comprises: a step of discharging the air jet from the first section of discharge (18) and the second discharge section (20) for removing dust from the cylindrical filter (10), wherein the air jet discharge from the first discharge section (18) and the air jet discharge from the second discharge section (18) discharge (20) are started with a time difference. 10. Dust removal method according to claim 9, characterized by the fact that the removal step is carried out while the time difference is changed between two air jet shots.