JPH09103708A - Dust collecting system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To detect the clogging of a cyclone to remove depositions in a cyclone system for removing dust in high temperature/pressure waste gas. SOLUTION: Pressure difference is set between a cyclone body 10 and a downstream part to generate descending flow pulses in the lower part of a cyclone, and particles 5 for scraping off which are fed from a cyclone inlet 14 is entrained in the descending flow pulses to remove depositions.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cyclone system for removing dust contained in exhaust gas of high temperature and high pressure, and further, when a cyclone is closed, a downflow pulse generated in the lower part of the cyclone is used to remove deposits on the closed part of the cyclone. About the system to do.

[0002]

2. Description of the Related Art A cyclone is widely used as a dust collector for removing dust contained in gas because it has a simple structure, has no moving parts, and does not impose a large cost burden on operation. The temperatures and pressures used are from the dedusting treatment of exhaust gas at room temperature and atmospheric pressure to the dedusting of cement burning gas.
Furthermore, it covers a wide range up to high temperature and high pressure areas such as catalyst recovery in catalytic reforming of petroleum.

When the cyclone is continuously operated, the collected dust may locally accumulate in the cyclone, block the gas flow passage in the cyclone, and stop the operation as a cyclone. Specifically, adherent dust accumulates at the stagnation point of the gas flow path such as the change area of the duct cross section or the vent part to form an aggregate, which grows by newly adhering dust. It may block the pipeline. Further, when used under high temperature conditions, not only the aggregate of dust particles may simply block the flow path, but solid phase reaction may proceed between particles to form a stronger solidified product.

As a method for avoiding the operation stoppage due to the blockage of the cyclone, a method in which a spare cyclone system is installed side by side, and when one is blocked, the other cyclone system is switched to is widely used. To remove the deposits, tap the outside of the cyclone container to drop the deposits, or install a steam or gas pipe at a position where the deposits easily occur, and intermittently blow it to grow the deposits. There are known ways to prevent this. Alternatively, Japanese Laid-Open Patent Publication No. 64-27656 discloses a method in which particles having a large particle size are thrown into a cyclone at the time of blockage to scrape off the deposits.

[0005]

The object of the present invention is to provide a solid-state reaction between dust particles collected in a cyclone,
It is to provide a means for removing the generated solidified product and preventing clogging of the flow path.

[0006]

[Means for Solving the Problems] In order to investigate the adhesion state of dust inside the cyclone, an acrylic cold model with an inner diameter of the outer cylinder of the cyclone body of 190 mm was made, and a gas containing dust was introduced to the inside of the cyclone. The flow condition and dust adhesion condition on the inner wall surface of the cyclone were investigated. As a result, as shown in FIG. 2, it was found that the deposit 55 was generated in the lower portion of the cyclone where the downward swirling flow 41 was reversed. When deposits were generated at this position, the deposits were hardly scraped even when the scraping particles 5 having a large particle size were introduced.

This is because even if the particles for scraping are entrained in the normal cyclone flow, as shown in FIG.
This is because the descending swirling flow 41 reverses and flows to the outlet 42 near the position where 5 is generated, and the scraping particles 5 drop from the flow and descend by gravity together with the collected dust.
If the deposit itself traces its origin, dust that has fallen out of the flow adheres to the inner wall for some reason, and it is impossible to scrape off the deposit with particles placed on the cyclone flow.

Further, when dust in the exhaust gas of high temperature and high pressure adheres, it is considered that a strong adherent substance is generated, and new measures are required. Especially highly reactive in dust,
For example, in the case of containing calcium or the like, when the aggregate of dust is kept in a high temperature atmosphere for a certain period of time, the reaction progresses between the dust particles to form a strong deposit. FIG. 3 shows an example. In this example, the dust recovered from the combustion exhaust gas from the pressurized fluidized bed was molded into a pellet having a diameter of 2 mm and a height of 2 mm, and the relationship between the pellet breaking strength and the dust particle size was shown when the pellet was held at 830 ° C. for 4 hours. However, the fracture strength increases as the particle size decreases, indicating that strong deposits are formed.

From the knowledge about the flow of particles in the cyclone obtained by the cold model, it was found that it is more effective to generate a strong downward flow in the lower part of the cyclone in order to scrape off the deposits. As a result of examining various methods for not only simply placing the scraping particles on the cyclone flow but also by imparting a strong downward flow to the cyclone flow, a powerful downward swirling flow is reached to the dust adhering position shown in FIG. It was found that adding blowdown to the flow in the cyclone is effective. That is, for example, if the differential pressure between the hopper and the cyclone main body under the cyclone is increased and a downward flow pulse is applied to the cyclone lower part by this differential pressure, a strong downward swirling flow reaches the dust adhesion position and scratches the adhered matter. Can be taken. By entraining the scraping particles in this flow, it is possible to impart a stronger scraping effect to these particles.

The downflow does not have to be generated continuously,
It is sufficient to continue the time for scraping off the deposit. Therefore, a pulsed downflow is sufficient. The advantage of this method is that in a high temperature and high pressure cyclone system, the pressure of the container on the downstream side is adjusted to generate a pressure difference between the cyclone side and the downstream side, and this pressure difference is used as the driving force to generate a strong downward flow. The pulse can be generated in the lower part of the cyclone, and a means for releasing the blockage of the cyclone can be obtained without adding new equipment. When there are many deposits or when a strong deposit is generated, a stronger scraping action can be provided by supplying particles for scraping the deposit.

The operation of the present invention will be described below with reference to FIG. As shown in FIG. 1, the blockage of the cyclone is detected by the temperature difference (T ₁ -T ₂ ) between the cyclone inlet 14 and the cyclone leg 12 and the pressure difference (P ₂ -P ₃ ) between the cyclone leg 12 and the chamber 13. Then, the scraping particles 5 are put into the cyclone flow from the scraping particle supply device 1, and subsequently, the pressure of the chamber portion 13 is reduced by the pressure adjusting device 34, and a strong downward flow 45 is applied to the cyclone leg portion 12. Give. As a result, the scraping particles 5 ride on the descending swirl flow 44 and scrape off the deposits 55 in the cyclone leg 12. Specifically, the pressure adjusting device 34 is used as another chamber, and a valve is provided between the chamber portion 13 and the pressure adjusting device 34. When the valve is closed, the pressure in this part is reduced, and then the pressure is reduced. It is also possible to open the valve and generate a downward flow.

As the means for detecting the cyclone blockage, other means than the temperature difference or the differential pressure can be used. The scraping particles have only to have a size and a specific gravity which are sufficiently larger than those of the dust collected and adhered, and there is no restriction on the particle size and properties.

After a lapse of a certain time from the occurrence of blockage, the introduction of the particles for scraping is stopped, the pressure in the chamber 13 is returned to the reference value, and the normal cyclone operation is resumed.

[0014]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings.

(Embodiment 1) In this embodiment, combustion exhaust gas from a pressurized fluidized bed boiler is dedusted, and the inner diameter of the outer cylinder is 780 mm and 6
This is an example in which the system according to the present invention is installed in a 50 mm two-stage cyclone. FIG. 4 shows the configuration of this embodiment. A small cyclone 19 is installed downstream of the blowdown line 49 of the main cyclone 18 installed in the main stream 48 of the gas flow.
The inlet gas temperature is 650 ° C. and the pressure is 8 atm. During normal operation, the main cyclone 18 is blown down by 2%, and the dust in this gas is collected through the cyclone 19. The dust collected by the cyclone is the chamber 13
From the screw feeder 31 to the relay hopper 32
Collected in. When the hopper 32 is full, the valve 62
Open and move to the lock hopper 33 for discharge.

The temperature difference between the cyclone inlet and the cyclone leg (T ₁ -T ₂ ) and the pressure difference between the cyclone leg and the chamber 13 (P ₂ -P ₃ ) are used to detect the blockage of the cyclone. (T ₁ -T ₂₎ is 100 ° C., the (P ₂ -P ₃₎ 400mm
When Aq is exceeded, it is determined that clogging has occurred, and the scraping particles are supplied from the scraping particle supply device 1 to the cyclone flow,
The inside of the lock hopper 33 is depressurized to atmospheric pressure with the valve 62 closed. Subsequently, the valve 61 is closed and the valve 62 is opened to generate a pulsed downward flow accompanied by scraping particles on the legs of the cyclone by the pressure difference between the lock hopper 33 and the main cyclone body 18. The descending flow scrapes off the adhering substances, and the scraping particles and the adhering substances scraped off are collected by the lock hopper 33.

(Embodiment 2) In this embodiment, the combustion exhaust gas from the pressurized fluidized bed boiler is dedusted, and the inner diameter of the outer cylinder is 780 mm.
It is an example in which the system according to the present invention is installed in a step cyclone. FIG. 5 shows the configuration of this embodiment. An air flow transfer line 46 is installed downstream of the chamber, and during normal operation, cyclone 1
0% is blown down by 2%, and the collected ash is blown down by the blown down gas and auxiliary air 47 to the relay hopper 3
Stored in 2. The inlet gas temperature is 650 ° C. and the pressure is 8 atm.

The temperature difference (T ₁ -T ₂ ) between the cyclone inlet and the cyclone leg and the pressure difference (P ₂ -P ₃ ) between the cyclone leg and the chamber 13 are used to detect the blockage of the cyclone. (T ₁ -T ₂₎ is 100 ° C., the (P ₂ -P ₃₎ 400mm
When Aq is exceeded, it is determined that clogging has occurred, and the scraping particles are supplied from the scraping particle supply device 1 to the cyclone flow,
The lock hopper 33 is depressurized to atmospheric pressure, the valve 63 is closed to stop the auxiliary air, the valve 61 is closed, and the valve 62 is closed.
The differential pressure between the lock hopper 33 and the main cyclone body 10 is used to generate a downward flow pulse accompanied by scraping particles on the legs of the cyclone. The descending flow scrapes off the adhering matter, and the scraping particles and the adhering matter scraped off are collected by the hopper 32.

(Embodiment 3) In this embodiment, the combustion exhaust gas from the pressurized fluidized bed boiler is dedusted, and the inner diameter of the outer cylinder is 780 mm, 7
This is an example in which the system according to the present invention is installed in a three-stage cyclone of 80 mm and 650 mm. FIG. 6 shows the configuration of this embodiment. A blowdown of 2% is applied to each of the cyclone 18 and the cyclone 19 installed in the main stream 48 of the gas flow, the blowdown line of the cyclone 18 is joined to the main stream 48 of the gas flow, and the blowdown line 49 of the cyclone 19 is connected. A small cyclone 20 is installed downstream. The inlet gas temperature is 650 ° C. and the pressure is 8 atm. The dust collected by the cyclone 18 and the cyclone 19 is transferred from the chambers 11 and 13 by the screw feeders 30 and 31 to the lock hoppers 33 and 36 via the relay hoppers 32 and 35 and discharged.

The temperature difference (T ₁ -T ₂ ) between the cyclone inlet and the cyclone leg and the differential pressure (P ₂ -P ₃ ) between the cyclone leg and the chamber 13 are used to detect the blockage of the cyclone. When the blockage of the cyclone 18 is detected by the same method as in the first embodiment, the scraping particles are fed from the scraping particle supply device 1 into the cyclone flow, and the inside of the lock hopper 33 is expanded with the valve 62 closed. Reduce pressure to atmospheric pressure. Subsequently, the valve 61 is closed and the valve 62 is opened, and a downflow pulse accompanied by scraping particles is generated in the leg portion of the cyclone due to the pressure difference between the lock hopper 33 and the cyclone 18. The descending flow scrapes off the adhering substances, and the scraping particles and the adhering substances scraped off are collected by the lock hopper 33.

(Embodiment 4) In this embodiment, the combustion exhaust gas from the pressurized fluidized bed boiler is dedusted, and the inner diameter of the outer cylinder is 780 mm, 7
This is an example in which the system according to the present invention is installed in a three-stage cyclone of 80 mm and 650 mm. FIG. 6 shows the configuration of this embodiment. A blowdown of 2% is applied to each of the cyclone 18 and the cyclone 19 installed in the main stream 48 of the gas flow, the blowdown line of the cyclone 18 is joined to the main stream 48 of the gas flow, and the blowdown line 49 of the cyclone 19 is connected. A small cyclone 20 is installed downstream. The inlet gas temperature is 650 ° C. and the pressure is 8 atm. The dust collected by the cyclone 18 and the cyclone 19 is transferred from the chambers 11 and 13 by the screw feeders 30 and 31 to the lock hoppers 33 and 36 via the relay hoppers 32 and 35 and discharged.

The temperature difference (T ₁ -T ₂ ) between the cyclone inlet and the cyclone leg and the pressure difference (P ₂ -P ₃ ) between the cyclone leg and the chamber 13 are used to detect the blockage of the cyclone. When the blockage of the cyclone 19 is detected by the same method as in the first embodiment, the inside of the lock hopper 36 is depressurized to the atmospheric pressure with the valve 64 closed. Subsequently, the valve 65 is closed and the valve 64 is opened, and a downflow pulse is generated in the leg portion of the cyclone due to the pressure difference between the lock hopper 36 and the cyclone 18. The descending flow scrapes off the adhering matter,
The adhered matter scraped off is collected by the lock hopper 36.

[0023]

According to the present invention, it is possible to minimize the addition of new equipment and efficiently remove dust strongly adhered to the inner surface of the cyclone due to sticking at high temperature when the cyclone is closed.

[Brief description of the drawings]

FIG. 1 is an explanatory view showing a motion state of scraping particles put into a cyclone flow provided with a downward flow.

FIG. 2 is an explanatory diagram showing a dust adhesion state in a cyclone.

FIG. 3 is a characteristic diagram showing the influence of dust particle size on the fracture strength of pellets obtained by heat treating pressurized fluidized bed combustion dust.

FIG. 4 is a system diagram showing an example in which the present invention is applied to a two-stage cyclone system.

FIG. 5 is a system diagram showing an example in which the present invention is applied to a cyclone system having an air flow transfer line.

FIG. 6 is a system diagram showing an example in which the present invention is applied to a three-stage cyclone system.

[Explanation of symbols]

1 ... Scraping particle supply device, 5 ... Scraping particles, 1
0 ... Cyclone body, 11, 13 ... Chamber, 12 ... Cyclone leg, 14 ... Cyclone inlet, 15 ... Cyclone outlet, 21 ... Pressure detecting means, 24 ... Temperature detecting means, 3
4 ... Pressure regulator, 41 ... Downward swirl flow, 42 ... Outlet gas flow, 45 ... Downdust flow.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Yasuo Yoshii 7-1 Omika-cho, Hitachi-shi, Ibaraki Hitachi Ltd. Hitachi Research Laboratory (72) Inventor Toru Inada 7-chome, Omika-cho, Hitachi-shi, Ibaraki No. 1 Hitachi Ltd., Hitachi Research Laboratory (72) Inventor Kazuo Ikeuchi 3-1-1, Saiwaicho, Hitachi City, Ibaraki Hitachi Ltd. Hitachi Factory, Hitachi (72) Inventor Masato Machida Ichiaki, Ibaraki Prefecture 3-1-1, Machi, Hitachi, Ltd. Hitachi factory

Claims (5)

[Claims] 1. A cyclone system for removing fine particles from high-temperature and high-pressure exhaust gas, wherein a downflow pulse is generated below the cyclone when the cyclone is closed, and the downflow pulse is used to remove the blocking material. Dust system. 2. A cyclone system for removing fine particles from high-temperature and high-pressure exhaust gas, having means for setting the pressure of a portion downstream of the cyclone to be lower than the pressure of the cyclone main body when the cyclone is closed. A dust collection system characterized in that a clogging material is removed by the generated downward flow pulse. 3. A cyclone system for removing fine particles from high-temperature and high-pressure exhaust gas, when the cyclone is closed, a means for setting the pressure of the portion downstream of the cyclone lower than the pressure of the cyclone body and a means for supplying particles to the cyclone inlet. And removing the occluding substance by entraining the particles supplied from the particle supply means in the downward flow pulse generated by the differential pressure. 4. The cyclone blockage is detected by the temperature of the lower portion of the cyclone and the pressure of the lower portion of the cyclone, and the pressure of the downstream portion of the cyclone is set lower than the pressure of the cyclone body. A dust collecting system for removing particles by supplying particles to the cyclone inlet and entraining the particles in a downward flow pulse generated by this differential pressure. 5. The cyclone blockage is detected by the temperature of the lower portion of the cyclone and the pressure of the lower portion of the cyclone according to claim 2, and the pressure of the portion downstream of the cyclone is set lower than the pressure of the cyclone main body. A dust collection system that removes blockages by the downward flow pulse generated by this pressure difference.