JP6787739B2 - Filter mounting structure of filtration type dust collector - Google Patents

Description

The present invention relates to a filter mounting structure of a filtration type dust collector that removes fine dust such as incineration ash contained in exhaust gas discharged from a waste incinerator, a sewage sludge incinerator, or the like.

Exhaust gas emitted from waste incinerators and sewage sludge incinerators contains fine dust such as ash, metals, unburned carbon and organic substances, so removal treatment is required when discharging. As one of the devices for removing the fine dust, there is a filtration type dust collector.
Generally, a filtration type dust collector has a structure in which exhaust gas flows in from below the device, dust is collected by a filter mounted in the device, and the filtered exhaust gas is discharged from above the device.
Conventionally, as a filter, a filter cloth for collecting dust called a bug filter has been used, but in recent years, a ceramic filter capable of dealing with high-temperature exhaust gas has been used.
FIG. 10 is a cross-sectional view showing an example of a filtration type dust collector 30 using the ceramic filter. In the filtration type dust collector 30, a ceramic filter (50) having a long cylindrical main body portion (51) with one end closed and a flange (57) at the open end portion (52) at the other end is used. (See FIG. 11).
The inside of the housing 31 of the filtration type dust collector 30 shown in FIG. 10 is divided into a lower dust collecting chamber 33 and an upper exhaust chamber 34 by a cell plate (partition wall) 32, and a group of filters are provided in the cell plate 32. 35 is attached. Then, the lower dust collecting chamber 33 has an intake port 37 for taking in exhaust gas containing dust, and the upper exhaust chamber 34 has a discharge port 38 for discharging the purified gas filtered by the filter 35 to the outside of the dust collecting device 30. Is provided.
Exhaust gas containing dust is introduced into the dust collection chamber 33 from the intake port 37 by an air supply device or an intake device (neither is shown), and while passing from the outer wall surface to the inner wall surface of the ceramic filter 35. The dust is filtered, and the filtered clean gas is taken out of the device from the discharge port 38 provided in the exhaust chamber 34.
In the exhaust chamber 34 of the housing 31, the fine dust collected by each of the filters 35 is blown down into the dust collecting chamber 33, and a jet stream for removing dust is ejected to stably maintain the function of the filter 35. An air pipe 36 is provided.
FIG. 11 is a cross-sectional view showing a conventional filter used for such exhaust gas purification and a structure for mounting the filter on a cell plate.
As shown in the figure, the ceramic filter 50 shown in FIG. 11 has a cylindrical shape having an opening 52 on one end side and a closed end side 53, and the outer peripheral surface 54 of the cylindrical shape. A reinforcing member 56 made of a metal material is installed between the inner peripheral surface 55 and the inner peripheral surface 55. Further, the flange portion 57 is formed so as to radiate from the opening 52.
In the ceramic filter 50 configured in this way, the flange portion 57 formed in the opening 52 is fixed by tightening the pressing plate 58 and the receiving plate 59 with bolts 60 (Patent Document 1).
In addition to the above, there are the following filter mounting structures.
As shown in FIG. 12, a cylindrical shape having a flange 63b in the opening 63a inside a ceramic filter 61 formed by sintering a cylindrical ceramic material having an opening on the other end side with one end closed. A retainer composed of a base 63, a plurality of shaft steel wires 64 vertically laid on the inner wall of the base 63 at equal intervals, and a plurality of ring-shaped steel wires 65 inscribed and fixed to the plurality of shaft steel wires 64. There is a mounting structure in which 62 is mounted and the ceramic filter 61, retainer 62 and packing 66 are sandwiched and fixed between the cell plate 67 and the holding plate 68. At the same time, the crushed size of the packing 66 determined by the tightening condition and the flange portion of the ceramic filter 61. A collar 69 is provided so as to limit the total height of the thickness of 61d and the thickness of the flange 63b of the retainer 62 so as not to impair the effect of the packing 66, and the collar 69 is fastened and fixed by the bolt 70 and the nut 71.

Japanese Unexamined Patent Publication No. 2013-94730

The invention of Patent Document 1 is formed by sintering a ceramic material into a cylindrical shape having an opening 52 on one end side and a closed end side 53, and the outer peripheral surface 54 and the inner peripheral surface 55 of the cylindrical shape. A reinforcing member 56 made of a metal material is installed between the ceramic filter 50 to increase the rigidity of the entire ceramic filter 50 and improve the earthquake resistance. However, as a material of the ceramic filter, a compound in which a molding aid is added to SiC particles. The compound is laminated on a semi-cylindrical mold with a thickness of about half of the thickness intended as the thickness of the ceramic filter, and then a reinforcing member 56 to be installed in the ceramic filter 50 is placed on the surface of the laminated compound. A semi-cylindrical ceramic filter 50 is formed by laminating the compound on the mixture, and the formed semi-cylindrical ceramic filter 50 is sufficiently dried and then sintered at a high temperature of 2000 ° C. or higher. As a result, a ceramic filter 50 having a substantially semi-cylindrical shape is completed. Then, two ceramic filters 50 having a substantially semi-cylindrical shape manufactured in this manner are attached and joined with an adhesive such as an adhesive to complete one ceramic filter 50. Therefore, there is a problem that many steps are required for manufacturing and the manufacturing cost is high.
Further, in the ceramic filter 50, a flange portion 57 is formed so as to radiate from the opening 52, and the flange portion 57 is fixed by tightening the pressing plate 58 and the receiving plate 59 with bolts 60. In the reinforcing member 56 integrated with the ceramic filter, the deflection due to the rolling of the ceramic filter 50 is transmitted to the reinforcing member 56 due to vibration caused by an earthquake or the like, and the reinforcing member 56 bends and synchronizes. In this way, the shaking of the ceramic filter 50 is transmitted to the flange portion 57 of the ceramic filter 50 containing the flange of the reinforcing member 56, but the flange of the reinforcing member 56 also synchronizes with the movement of the flange portion 57 of the shaking ceramic filter 50. Due to the swaying moment of the ceramic filter 50, the flange of the reinforcing member 56 exerts a force on the flange portion 57 of the ceramic filter 50, causing cracks and breakage in the vicinity of the flange portion 57 made of brittle ceramic, resulting in the ceramic filter. 50 is easily damaged.
Further, in the other filter mounting structure, when an earthquake occurs or the like, the deflection due to the rolling of the ceramic filter 61 is transmitted to the retainer 62, and when the retainer 62 bends in synchronization, the shaking of the ceramic filter 61 causes the ceramic filter 61 to bend. Since the flange 63b of the base 63 of the retainer 62 is only pressed from above by the holding plate 68, the flange 63b of the base 63 of the retainer 62 also synchronizes with the movement of the flange 61d of the swaying ceramic filter 61. The entire ceramic filter 61 and the entire retainer 62 are synchronized with each other, and the horizontal amplitude at the time of rolling becomes large. Therefore, the above-mentioned fixing method of the retainer 62 and its strength sufficiently provide sufficient rolling of the ceramic filter 61. Could not be suppressed.
Further, the strength of the flange of the retainer 62 is not sufficient, and the height of the base of the retainer is too short as a reinforcing material for the flange 61d of the ceramic filter 61, so that the neck portion of the flange 61d of the ceramic filter 61 swings horizontally. It was sometimes broken by the moment.
Further, since the ceramic filter 61, the retainer 62, and the packing 66 are fixed only by the pressing plate 68, the flanges of the ceramic filter 61 and the retainer 62 fluctuate at the soft portion of the packing 66, thereby preventing the ceramic filter 61 from wobbling horizontally. It's difficult.

The present invention has been made in view of the above-mentioned problems, and by imparting sufficient seismic resistance, the ceramic filter is less likely to be damaged, and a filter mounting structure of a filtration type dust collector having good reliability is provided. The purpose is to do.

The present inventors have solved the above problems by the following means.
[1] In the mounting structure of the ceramic filter to the filtration type dust collector
One end is closed, the other end has an opening (1b), and the other end is inserted into a mounting hole (6a) formed in the cell plate (6) in the filtration type dust collector. Cylindrical ceramic filter (1) having a flange (1c)
A holding plate (8) for fixing the flange (1c) of the ceramic filter (1) installed on the upper surface of the cell plate (6) to the cell plate (6).
A retainer having a base (2a) having a flange (2b) in the opening (2c) inserted through the opening (8a) of the holding plate (8) and the opening (1b) of the ceramic filter (1). (2) and
Fixtures (11, 12) for fixing the holding plate (8) to the cell plate (6),
It is inserted through the opening (8a) provided in the holding plate (8), inserted into the retainer (2) installed on the upper surface of the holding plate (8), and is inserted into the retainer (2) by the holding plate (8). ) With a cylindrical reinforcing tool (9) having a flange (9c) in the opening (9b) that sandwiches the flange (2b).
A mounting tool (13) for fixing the reinforcing tool (9) to the holding plate (8),
The filter mounting structure of the filtration type dust collector, which is characterized by being composed of.
[2] In the mounting structure of the ceramic filter to the filtration type dust collector
One end is closed, the other end has an opening (1b), and the other end is inserted into a mounting hole (6a) formed in the cell plate (6) in the filtration type dust collector. Cylindrical ceramic filter (1) having a flange (1c)
A holding plate (8) for fixing the flange (1c) of the ceramic filter (1) installed on the upper surface of the cell plate (6) to the cell plate (6).
A retainer having a base (2a) having a flange (2b) in the opening (2c) inserted through the opening (8a) of the holding plate (8) and the opening (1b) of the ceramic filter (1). (2) and
It is inserted through the opening (8a) provided in the holding plate (8), inserted into the retainer (2) installed on the upper surface of the holding plate (8), and is inserted into the retainer (2) by the holding plate (8). ) With a cylindrical reinforcing tool (14) having a flange (14b) in the opening (14a) that sandwiches the flange (2b).
Fixtures (11, 12) for fixing the holding plate (8) to the cell plate (6) and fixing the reinforcing tool (14) to the holding plate (8).
The filter mounting structure of the filtration type dust collector, which is characterized by being composed of.
[3] In the mounting structure of the ceramic filter to the over-type dust collector
One end is closed, the other end has an opening (1b), and the other end is inserted into a mounting hole (6a) formed in the cell plate (6) in the filtration type dust collector. Cylindrical ceramic filter (1) having a flange (1c)
A retainer (2) inserted through the opening (1b) of the ceramic filter (1) and having a base (2a) provided with a flange (2b) in the opening (2c).
The flange (1c) of the ceramic filter (1) installed on the upper surface of the cell plate (6) and the flange (2b) of the retainer (2) are sandwiched between the cell plate (6) and the opening (15a). A cylindrical reinforcing tool (15) inserted inside the retainer (2) having a flange (15b), and mounting tools (11, 12) for fixing the reinforcing tool (15) to the cell plate (6).
The filter mounting structure of the filtration type dust collector, which is characterized by being composed of.
[4] In the mounting structure of the ceramic filter to the filtration type dust collector
One end is closed, the other end has an opening (1b), and the other end is inserted into a mounting hole (6a) formed in the cell plate (6) in the filtration type dust collector. Cylindrical ceramic filter (1) having a flange (1c)
The ceramic filter (1) has a base (16a) in which a flange (16b) is provided in the opening (16c) inserted from the opening (1b), and the length of the base (16a) in the vertical direction is the said. A retainer (16) formed so as to be located below the position of the lower surface of the cell plate (6) when attached to a ceramic filter (1) attached to a predetermined position of the cell plate (6). When,
Fixtures (11, 12) for fixing the retainer (16) to the cell plate (6), and
The filter mounting structure of the filtration type dust collector, which is characterized by being composed of.

According to the inventions of [1] to [3], since the retainer and the reinforcing tool are inserted and mounted inside the ceramic filter, the retainer and the reinforcing tool can withstand the force applied to the ceramic filter due to the vibration such as an earthquake, and the ceramic. Since the filter runout is suppressed by the filter, it is possible to prevent shearing and breakage at the neck portion of the ceramic filter near the cell plate.
Further, according to the invention of [4], since the retainer is composed of a long rigid base, the same effect as in [1] to [3] can be obtained.

It is sectional drawing which shows the mounting structure of the filter of the filtration type dust collector which concerns on 1st Example. It is a perspective view which shows the structure of the ceramic filter, the retainer and the reinforcing tool which concerns on 1st Example. It is a schematic diagram which shows the whole structure of the filter attachment structure of the filtration type dust collector which concerns on 2nd Example. It is a schematic diagram which shows the whole structure of the filter attachment structure of the filtration type dust collector which concerns on 3rd Example. It is a schematic diagram which shows the whole structure of the filter attachment structure of the filtration type dust collector which concerns on 4th Example. It is a figure which shows the waveform in the sweep test. It is a figure which shows the result of the sweep test. It is a figure which shows the waveform in the real wave test. It is a figure which shows the result of the real wave test. It is a cross section which shows the structure of a filtration type dust collector. It is a cross-sectional view which shows the structure of the conventional ceramic filter. It is a schematic diagram which shows the mounting structure of the filter of the conventional filtration type dust collector.

Hereinafter, preferred embodiments of the present invention will be described in detail exemplary with reference to the drawings. However, the dimensions, materials, shapes, relative arrangements, etc. of the components described in this embodiment are not intended to limit the scope of the present invention to them unless otherwise specified, and are merely explanatory examples. Not too much.

(First Example)
FIG. 1 is a cross-sectional view showing a support structure of a filter of the filtration type dust collector according to the first embodiment, and FIG. 2 is a perspective view showing a structure of a ceramic filter and a retainer.
As shown in FIGS. 1 and 2, in the ceramic filter 1, one end of a main body 1a having a long bottomed cylindrical shape is closed and the other end has an opening 1b, and the opening 1b has a flange 1c. Is formed.
In the present embodiment, the ceramic filter 1 has a length of 3 m, an outer diameter of 150 mm, and an inner diameter of 110 mm.
The retainer 2 has a cylindrical base 2a having a flange 2b (hereinafter, referred to as a retainer flange) in the opening 2c. In this embodiment, the retainer 2 is a plurality of shaft steel wires 4 arranged on the inner wall of the base 2a along a cylindrical cross-sectional circumferential direction, and the base inscribed and fixed to the plurality of shaft steel wires 4. Although the one formed from a plurality of ring-shaped steel wires 5 formed along the circumferential direction of the cross section of the cylindrical shape of 2a is adopted, the present invention is not limited to the above configuration and is formed of punching metal or the like. It can be selected and adopted as appropriate.
The retainer 2 is inserted into the ceramic filter 1 to reinforce the strength of the ceramic filter 1, and its outer diameter and length are configured with dimensions corresponding to the ceramic filter 1.
Reference numeral 6 denotes a cell plate that divides the inside of the housing of the filtration type dust collector into a lower dust collecting chamber and an upper exhaust chamber, and the ceramic filter 1 is inserted through a mounting hole 6a formed in the cell plate 6. It is attached.
7 is a seamless ring-shaped packing having an opening made of an elastic material that prevents exhaust gas containing dust from flowing from the dust collecting chamber of the filtration type dust collector to the exhaust chamber, 8 is an upper holding plate, and 9 is both ends. This is a cylindrical reinforcing tool having an opening 9b at one end of a long cylindrical main body portion 9a having an open portion and a flange 9c formed in the opening 9b.
The reinforcing tool 9 is made of a steel pipe having strength such as Steel Use Stainless.
If the reinforcing tool 9 is too short, seismic performance cannot be obtained. Further, the longer the length, the higher the seismic performance, but if it is too long, the filtration function deteriorates, which adversely affects the backwash performance. Therefore, it is preferable to set the length in consideration of the filtration function.
In the present embodiment, the reinforcing tool 9 is formed to have a length of 500 mm and a thickness of 2.3 mm in consideration of strength, but the present invention is not limited to these, and when the reinforcing tool is lengthened, it is formed into a pipe. It is conceivable to prevent adverse effects on the backwash performance by making holes or using a punching plate in a tubular shape.
10 is a color. The collar 10 is a packing 7 provided on the cell plate 6 when the ceramic filter 1 is sandwiched between the cell plate 6 and the holding plate 8 and tightened with a fixture composed of a bolt 11 and a nut 12 to support and fix the ceramic filter 1 to the cell plate 6. It is composed of the total height of the crushed size of the filter 1 and the thickness of the flange 1c of the filter 1.
The filter support structure of the filtration type dust collector according to the present invention includes a ceramic filter 1, a packing 7, and a collar 10 installed on the upper surface of the cell plate 6 of the filtration type dust collector configured as described above. The retainer 2 mounted inside the ceramic filter 1 is sandwiched between the holding plate 8 and the reinforcing tool 9 while being sandwiched between the holding plate 8 and the fixing tool consisting of the bolt 11 and the nut 12. It is fixed with a fixture and attached to the cell plate 6 of the filtration type dust collector.

(Mounting method)
Subsequently, an example of a method of mounting and supporting the above-mentioned ceramic filter 1 on the cell plate 6 of the filtration type dust collector will be described.
a. The ceramic filter mounting holes 6a provided at predetermined positions of the cell plate 6 provided in the housing of the filtration type dust collector and the opening of the packing 7 are aligned, and the packing 7 is installed on the upper surface of the cell plate 6.
b. The ceramic filter 1 is inserted (dropped) through the filter mounting hole 6a of the cell plate 6 and the opening of the packing 7, and is installed on the upper surface of the cell plate 6 via the packing 7.
c. Subsequently, the collar 10 is fixed to the upper surface of the cell plate 6, and the holding plate 8 is fitted to the bolt 11 provided in the cell plate 6 through the mounting holes provided in the holding plate 8 to form the ceramic filter 1. It is installed on the upper surface and fixed to the cell plate 6 with fixtures (bolts 11 and nuts 12).
d. Subsequently, the retainer 2 is inserted into the ceramic filter 1 from the retainer mounting hole 8a provided in the holding plate 8 until the retainer flange 2b is stopped by the upper surface of the holding plate 8.
e. Finally, the reinforcing tool 9 is inserted into the retainer 2 until it is stopped by the retainer flange 2b, the retainer is sandwiched between the holding plate 8 and the reinforcing tool 9, the mounting tool 13 is tightened, and the ceramic filter 1 is mounted and fixed to the cell plate 6. To do.

(Second Example)
FIG. 3 is a schematic view showing the overall configuration of the support structure of the filter of the filtration type dust collector according to the second embodiment.
As shown in the figure, the cylindrical reinforcing tool 14 has a flange 14b in the opening 14a, and the outer diameter of the flange 14b is formed to be substantially the same as the width of the holding plate 8.
(Mounting method)
Subsequently, an example of a method of mounting and supporting the above-mentioned ceramic filter 1 on the cell plate 6 of the filtration type dust collector will be described.
a. The ceramic filter mounting holes 6a provided at predetermined positions of the cell plate 6 provided in the housing of the filtration type dust collector and the opening of the packing 7 are aligned, and the packing 7 is installed on the upper surface of the cell plate 6.
b. The ceramic filter 1 is inserted (dropped) through the filter mounting hole 6a of the cell plate 6 and the opening of the packing 7, and is installed on the upper surface of the cell plate 6 via the packing 7.
c. Subsequently, the collar 10 is fixed to the upper surface of the cell plate 6, and the holding plate 8 is fitted to the bolt 11 provided in the cell plate 6 through the mounting holes provided in the holding plate 8 to form the ceramic filter 1. Install on the top surface.
d. Subsequently, the retainer 2 is inserted into the ceramic filter 1 from the retainer mounting hole 8a provided in the holding plate 8 until the retainer flange 2b is stopped by the upper surface of the holding plate 8.
e. Finally, the reinforcing tool 14 is inserted into the retainer 2 until it is stopped by the retainer flange 2b, the retainer flange 2b is sandwiched between the holding plate 8 and the reinforcing tool 14, and the ceramic filter is tightened with the fixtures (bolts 11 and nuts 12). 1 is attached and fixed to the cell plate 6.

(Third Example)
FIG. 4 is a schematic view showing the overall configuration of the support structure of the filter of the filtration type dust collector according to the third embodiment.
As shown in the figure, the cylindrical reinforcing tool 15 has a flange 15b in the opening 15a.
(Mounting method)
Subsequently, an example of a method of mounting and supporting the above-mentioned ceramic filter 1 on the cell plate 6 of the filtration type dust collector will be described.
a. The ceramic filter mounting holes 6a provided at predetermined positions of the cell plate 6 provided in the housing of the filtration type dust collector and the opening of the packing 7 are aligned, and the packing 7 is installed on the upper surface of the cell plate 6.
b. The ceramic filter 1 is inserted (dropped) through the filter mounting hole 6a of the cell plate 6 and the opening of the packing 7, and is installed on the upper surface of the cell plate 6 via the packing 7.
c. Subsequently, the retainer 2 is inserted into and mounted inside the ceramic filter 1 from the opening 1b of the ceramic filter 1 until it is stopped by the flange 1c of the ceramic filter 1.
d. Subsequently, the collar 10 is fixed to the upper surface of the cell plate 6, the reinforcing tool 15 is inserted into the retainer 2 until it is stopped by the retainer flange 2b, and the cell plate 6 and the reinforcing tool 15 are used to insert the reinforcing tool 15 into the flange 1c of the ceramic filter 1. And the retainer flange 2b is sandwiched and tightened with fixtures (bolts 11 and nuts 12), and the ceramic filter 1 is attached and fixed to the cell plate 6.

(Fourth Example)
FIG. 5 is a schematic view showing the overall configuration of the support structure of the filter of the filtration type dust collector according to the fourth embodiment.
The retainer 16 has a cylindrical base 16a having a flange 16b (hereinafter, referred to as a retainer flange) in the opening 16c.
As shown in the figure, the length of the vertical cylindrical portion of the base 16a provided on the retainer 16 is the cell plate when the retainer 16 is attached to the ceramic filter 1 attached to a predetermined position of the cell plate 6. The length is formed so as to be located below the position of the lower surface of 6.
By providing the function of the reinforcing tool by the base 16a of the retainer 16 formed in this way, the reinforcing tool in the first to third embodiments is omitted.
(Mounting method)
Subsequently, an example of a method of mounting and supporting the above-mentioned ceramic filter 1 on the cell plate 6 of the filtration type dust collector will be described.
a. The ceramic filter mounting holes 6a provided at predetermined positions of the cell plate 6 provided in the housing of the filtration type dust collector and the opening of the packing 7 are aligned, and the packing 7 is installed on the upper surface of the cell plate 6.
b. The ceramic filter 1 is inserted (dropped) through the filter mounting hole 6a of the cell plate 6 and the opening of the packing 7, and is installed on the upper surface of the cell plate 6 via the packing 7.
c. Subsequently, the collar 10 is fixed to the upper surface of the cell plate 6, and the retainer 16 is inserted into the ceramic filter 1 from the opening 1b of the ceramic filter 1 until it is stopped by the flange 1c of the ceramic filter 1. The ceramic filter 1 is sandwiched between the retainer flange 16b and tightened with fixtures (bolts 11 and nuts 12) to support and fix the ceramic filter 1 to the cell plate 6.

In order to compare the performance of the filter mounting structure of the conventional filtration type dust collector with the rolling motion of the filter mounting structure of the present invention, a general vibration test device (IMV Co., Ltd., model: DS-3600- 24L, maximum loading: 1,500kg) to Japanese Industrial Standards JIS C600726-2-6 (environmental test method: sine wave vibration test method) and JIS C6000068-3-3 (environmental test method: seismic test method guideline) Two types of dynamic tests, a sweep test and a real wave test, were performed according to the specified method.
The sweep test is an evaluation of intensity that does not depend on the seismic waveform, and is performed by continuously adding the vibration frequency near the natural period (resonance point) of the filter at a constant acceleration. The actual wave test is off the Pacific coast of Tohoku region in 2011. The seismic waveform of the earthquake (seismic intensity 6 upper) was used.
In the sweep test, a ceramic filter was attached to the vibration test device, and strong vibrations were sequentially applied from weak vibrations to observe the effects on the ceramic filters (cracks, breakage, etc.).
Specifically, a sample test of four tests using the conventional filter mounting structure,
The sample test of four tests was carried out by the mounting structure of the filter of this invention.

FIG. 6 is a diagram showing a waveform in the sweep test.
In the figure, the vertical axis represents the acceleration of vibration applied to the filter support structure, and the horizontal axis represents the elapsed time of vibration.
The sweep test is a test in which the number of laps is changed from high to low with a sine wave of constant acceleration. The sweep range is 6 to 1 Hz (filter resonance point 2 to 4 Hz), and the sweep speed is 1 octave / minute. Since continuous vibration is performed at a constant acceleration near the resonance point, the seismic performance was evaluated under stricter conditions than the actual seismic waveform test. Note that 1 octave / minute is a speed at which the frequency doubles in 1 minute.

FIG. 7 is a diagram showing the results of the above sweep test.
As is clear from the figure, in the conventional filter mounting structure, the filter was damaged when the acceleration exceeded 80 gal for all four in four sample tests, but in the filter mounting structure of the present invention, four times. In the sample test, the filter was not damaged when the acceleration of all four was less than 220 gal.

8A and 8B are diagrams showing waveforms in a real wave test, in which FIG. 8A represents a waveform in the east-west direction and FIG. 8B represents a waveform in the vertical direction.
This waveform is of the 2011 Tohoku-Pacific Ocean Earthquake in Furukawamikkamachi, Osaki City, Miyagi Prefecture, with a seismic intensity of 6 upper [measured seismic intensity 6.2] and a maximum horizontal acceleration of about 460 gal [east-west direction]. In this experiment, the effect on the ceramic filter was observed while gradually increasing the vibration of this waveform from weak acceleration.
In real-wave tests, conventional retainers are expected to have lower seismic intensity than seismic retainers, and given the conventional seismic waveforms of the Tohoku Pacific Ocean Offshore Earthquake, there are parts of the waveform that have large accelerations. Since it is not possible to control whether or not the seismic intensity (acceleration) is smaller than that of the seismic retainer, the test was conducted by adjusting the output of the seismic waveform to a smaller size.
In the actual wave test, a ceramic filter was attached to the vibration test apparatus, and the influence (cracks, breakage, etc.) on the ceramic filter was observed while gradually increasing the vibration of the waveform from a weak acceleration.
Specifically, in the conventional filter mounting structure, 9 sample tests were performed, and in the filter mounting structure of the present invention, 9 sample tests were performed.

FIG. 9 is a diagram showing the results of the actual wave test.
As is clear from the figure, in the conventional filter mounting structure, in 9 sample tests, the filter is damaged when the acceleration exceeds 160 gal, and the other filters are damaged when the acceleration exceeds about 290 gal. However, in the filter mounting structure of the present invention, all nine filters were not damaged up to an acceleration of 440 gal.

The test results are summarized in Table 1.

As is clear from the table, in the conventional filter mounting structure, damage occurred when the acceleration exceeded 80 gal in the sweep test, but the filter support structure of the present invention has a seismic strength of 220 gal or more in acceleration.
Further, in the conventional filter mounting structure, in the actual wave test, when the acceleration exceeds 160 gal, the file is damaged, and when the acceleration exceeds 290 gal, all the filters are damaged. However, in the filter support structure of the present invention, the file is damaged. The filter was not damaged up to an acceleration of 440 gal.

As described above, according to the filter mounting structure of the filtration type dust collector according to the present embodiment, a relatively flexible ceramic filter made by sintering a ceramic material is provided, and a retainer and a reinforcing tool are provided inside the ceramic filter. Since it is inserted and attached, the retainer and reinforcing tool can withstand the force applied to the ceramic filter due to runout such as an earthquake, and the ceramic filter suppresses filter runout, preventing damage to the neck of the ceramic filter near the cell plate. It is possible to provide a filter mounting structure of a filtration type dust collector having good reliability.
Further, since the retainer is composed of a long rigid base, it is possible to provide a filter mounting structure of a filtration type dust collector having good reliability as described above.

The present invention can be used for a ceramic filter mounting structure of a filtration type dust collector that removes incineration ash and the like contained in exhaust gas discharged from a waste incinerator, a sewage sludge incinerator, and the like.

1 Ceramic filter 2 Retainer 2a Base 2b Flange 4 Shaft steel wire 5 Ring-shaped steel wire 6 Cell plate 7 Packing 8 Holding plate 9, 14, 15 Reinforcing tool 10 Color 11 Bolt 12 Nut 13 Mounting tool

Claims (3)

In the mounting structure of the ceramic filter to the filtration type dust collector
One end is closed, the other end has an opening (1b), and the other end is inserted into a mounting hole (6a) formed in the cell plate (6) in the filtration type dust collector. Cylindrical ceramic filter (1) having a flange (1c)
A holding plate (8) for fixing the flange (1c) of the ceramic filter (1) installed on the upper surface of the cell plate (6) to the cell plate (6).
A retainer having a base (2a) having a flange (2b) in the opening (2c) inserted through the opening (8a) of the holding plate (8) and the opening (1b) of the ceramic filter (1). (2) and
Fixtures (11, 12) for fixing the holding plate (8) to the cell plate (6),
It is inserted through the opening (8a) provided in the holding plate (8), inserted into the retainer (2) installed on the upper surface of the holding plate (8), and is inserted into the retainer (2) by the holding plate (8). ) With a cylindrical reinforcing tool (9) having a flange (9c) in the opening (9b) that sandwiches the flange (2b).
A mounting tool (13) for fixing the reinforcing tool (9) to the holding plate (8),
The filter mounting structure of the filtration type dust collector, which is characterized by being composed of. In the mounting structure of the ceramic filter to the filtration type dust collector
One end is closed, the other end has an opening (1b), and the other end is inserted into a mounting hole (6a) formed in the cell plate (6) in the filtration type dust collector. Cylindrical ceramic filter (1) having a flange (1c)
A holding plate (8) for fixing the flange (1c) of the ceramic filter (1) installed on the upper surface of the cell plate (6) to the cell plate (6).
A retainer having a base (2a) having a flange (2b) in the opening (2c) inserted through the opening (8a) of the holding plate (8) and the opening (1b) of the ceramic filter (1). (2) and
It is inserted through the opening (8a) provided in the holding plate (8), inserted into the retainer (2) installed on the upper surface of the holding plate (8), and is inserted into the retainer (2) by the holding plate (8). ) With a cylindrical reinforcing tool (14) having a flange (14b) in the opening (14a) that sandwiches the flange (2b).
Fixtures (11, 12) for fixing the holding plate (8) to the cell plate (6) and fixing the reinforcing tool (14) to the holding plate (8).
The filter mounting structure of the filtration type dust collector, which is characterized by being composed of. In the mounting structure of the ceramic filter to the filtration type dust collector
One end is closed, the other end has an opening (1b), and the other end is inserted into a mounting hole (6a) formed in the cell plate (6) in the filtration type dust collector. Cylindrical ceramic filter (1) having a flange (1c)
A retainer (2) inserted through the opening (1b) of the ceramic filter (1) and having a base (2a) provided with a flange (2b) in the opening (2c).
The flange (1c) of the ceramic filter (1) installed on the upper surface of the cell plate (6) and the flange (2b) of the retainer (2) are sandwiched between the cell plate (6) and the opening (15a). A cylindrical reinforcing tool (15) inserted inside the retainer (2) having a flange (15b), and mounting tools (11, 12) for fixing the reinforcing tool (15) to the cell plate (6).
The filter mounting structure of the filtration type dust collector, which is characterized by being composed of.

Images