KR101049713B1 - Waste Gypsum Sludge Dehydrator from Wet Desulfurization of Power Plant - Google Patents

Abstract

The present invention is formed through the periphery and protrusions formed on the outer peripheral surface and divided into the cylindrical portion and the tapered portion to dewater the sludge generated when the sulfur generated from the combustion of the power plant is desulfurized, casing to form and rotate the mesh network on the inner peripheral surface The sludge dewatered by centrifugal force is quickly discharged by the tapered portion, and an air spray pipe is formed on the outer part of the casing to clean the holes of the mesh net and the scattering of water when the sludge is dewatered. The air spray pipe is formed in the housing which covers the outer circumferential surface of the casing together with the compressor to clean the through holes of the casing, and the dewatering device is configured to detach the sludge attached to the mesh network by the action of a scraper formed in the stirrer inside the mesh network. I would like to.

Casing, Mesh Network, Scraper

Description

The dehydration device of the waste gypsum sluge generated in the process wet desulfurization of electric power station

The present invention relates to a dewatering device for dewatering sludge generated when wet sulfur is generated from combustion of a power plant. Specifically, the dewatering device is formed of a cylindrical portion and a tapered portion and has a mesh of 200 to 250 mesh over its inner circumference. The sludge is fixed to the frame so that the casing with protrusions and holes formed on the outer periphery of the mesh is rotated and the sludge flowing into the casing is dehydrated and dehydrated by centrifugal force by the rotation of the casing. In order to prevent the dehydration effect from being reduced by closing the hole, a stirrer is formed inside the casing over the length of the casing, and a scraper formed in the stirrer is formed to detach the sludge attached to the mesh network, and the housing is covered with the housing outside the casing. Air from the air spray pipe exposed inside is injected into the through hole of the casing The present invention relates to a device for dewatering and discharging while desorbing sludge attached to a through hole.

Sulfur generated from the combustion of fuel in a power plant has a problem in that hot depressurized water (steam) and quicklime react in a desulfurizer to form a thin sludge slaked gypsum sludge, which is disposed of in nature to pollute water and pollute soil. .

The present invention is formed in a cylindrical shape and a tapered shape, the sludge introduced during rotation can be automatically discharged in the direction of the discharge port which is the end of the tapered portion, the casing is formed, a plurality of through holes perforated over the outer peripheral surface and the inner peripheral surface of the casing is formed, the casing A mesh network of 200 to 250 mesh is formed on the inner circumferential surface, and the scraper of the agitator and the scrubber of the stirring furnace are fixed and rotated over the inner circumferential surface of the mesh network to separate the sludge attached to the mesh network and rotate the casing. The sludge is meshed in the process of dewatering and dewatering the waste gypsum sludge introduced into the rotating casing by the air spray of the air spray pipe introduced from the upper surface of the housing formed over the outer circumference. Action of the scraper and the air injection pipe when it is attached to the hole of the It is an object of the present invention to provide a dewatering device for waste gypsum sludge which is configured to separate sludge attached to the mesh network by the action of the sludge and to clean the through holes of the casing to facilitate the dewatering of the sludge continuously.

The present invention is configured so that the casing of the body to facilitate discharge while the sludge is dewatered to form a tapered portion in the discharge port direction so that the sludge dehydrated by the function of the tapered portion can be quickly discharged.

In order to prevent the dehydration effect from being lowered due to the scattering of the waste gypsum sludge injected into the casing, the incoming gypsum sludge flows directly by the blocking plate.

A mesh net is formed on the inner surface of the casing to improve the dehydration effect of the sagure.

To increase the strength of the casing, a number of protrusions are formed over the outer circumferential surface of the casing.

In order to facilitate dehydration, a plurality of holes are drilled between the protrusions formed on the outer circumferential surface of the casing.

In order to remove sludge attached to the mesh network in close proximity to the mesh network, a spiral-shaped spiral scraper fixed to the stirring furnace and the stirring furnace is formed so that the scraper rotates while scratching the mesh network by the rotation of the stirrer. Allow the sludge attached to the mesh network to be detached.

Outside the casing, an air spray pipe is installed over the length of the casing so that the sludge attached to the through hole on the outer peripheral surface of the casing is detached into the casing and the mesh network.

The air injection pipe forms a housing on an outer circumferential surface of the casing to block water scattered while being dehydrated.

The lower part of the housing is provided with a water outlet so that water can be collected from the through hole of the casing.

The dewatering device according to the present invention can be installed in a narrow place has the effect of improving the purchasing power.

The dehydration apparatus according to the present invention is dehydrated by centrifugal force and can be quickly dehydrated because the dehydration speed can be adjusted by adjusting the rotational force.

Dehydration apparatus according to the present invention has the effect that the dewatered sludge is automatically discharged without additional additional equipment.

According to the present invention, a mesh net 12 formed to facilitate drainage over an inner circumferential surface, and a number of protrusions 36 protruding over an outer circumferential surface for improving strength are formed and drilled between the protrusions 36 to facilitate drainage. A casing 11 having a through hole 23 formed on an outer circumferential surface thereof, and a casing 11 formed integrally with the mesh net 12 are formed to rotate, and the casing 11 is disposed on the outer circumferential surface of the casing 11 outside the casing 11. A housing 13 formed to collect and discharge the dewatered water which is dehydrated by the centrifugal force of the casing 11, and an air spray pipe 33 fixed to the outside of the housing 13 and sprayed to a part of the outer circumferential surface of the casing 11. An agitator 27 including an air compressor 32, a scraper 31 formed to separate and stir the sludge attached to the inner circumferential surface of the mesh network 12, and formed at the end of the agitation furnace 29, and the agitator ( 27 of the casing 11 It is formed over the cylinder portion 14 and the tapered portion 15 so that the gypsum sludge is dehydrated and dehydrated by centrifugal force when the casing 11 rotates and attached to the through hole 23 and the mesh network 12 of the casing 11. The gypsum sludge is configured to be dehydrated and discharged while repeating the detaching operation by the scraper 31 formed in the stirring furnace 29 of the rotating shaft 28.

Figure 1 shows the appearance of the dewatering device of gypsum sludge.

2 shows the structure of the casing.

Figure 3 shows the inside of the dewatering device in detail.

Figure 4 shows the appearance of the casing in detail.

5 shows the stirrer and scraper in detail.

6 shows the air system in detail.

The present invention will be described in detail with reference to embodiments and drawings.

The casing 11 of this invention is formed with the cylindrical part 14 and the taper part 15. As shown in FIG.

The mesh net 12 is integrally formed on the inner circumferential surface of the casing 11.

As shown in FIG. 2, the casing 11 has a plurality of protrusions 36 formed on the outer circumferential surface to improve tension on the casing 11, and the sludge inside the casing 11 is disposed between the protrusions 36. A through hole 23 is formed to facilitate drainage.

The end of the cylindrical portion 14 of the casing 11 is fixed to the plate 16a so as to be pivotable to the bracket 17. The end of the tapered portion 15 is also supported by the plate 16b and the bearing 18 ) Is fixed to the arranged brackets 19 so as to facilitate high-speed rotation of the casing 11.

At the end of the tapered portion 15, the casing 11 is rotated in association with the power 24, and a discharge port 25 is formed to discharge the dewatered sludge.

Power 24 for rotating the casing 11 is formed with a rotational force of 250 ~ 600RPM is formed to control the number of revolutions to rotate the casing 11 at a speed of 60 ~ 150RPM.

It is formed to adjust the speed according to the structure and size of the casing (11).

Sludge inlet pipe 21 through which sludge flows into the inlet of the cylindrical portion 14 of the casing 11 extends to the inside of the casing 11, and an injection nozzle 22 for injecting sludge into the sludge inlet pipe 21 end. Is formed, and a blocking plate 37 is formed in front of the injection nozzle 22 to prevent the sludge powder from scattering.

The rotating shaft 28 of the stirrer 27 is formed in the center of the casing 11 over the length of the casing 11, and the rotating shaft 28 of the stirrer 27 has a cylindrical portion 14 as shown in FIG. 1. It is fixed to be exposed and fixed at the end and to be exposed and rotated at the tapered portion 15.

The stirring furnace 29 formed over the length of the rotating shaft 28 of the stirrer 27 is radially formed as shown in FIG. 4 and the stirring furnace 29 is fixed while proceeding in a screw shape alternately with the rotating shaft 28. It is.

An end portion of the stirring furnace 29 is formed to be close to the mesh network 12, and a scraper 31 having a floating shape is fixed.

Since the scraper 31 fixed to the end of the stirring furnace 29 is formed over the length of the rotating shaft 28, the stirrer 27 is formed to rotate in close proximity to the mesh network 12 while forming a screw shape as a whole. When rotating, the scraper 31 is formed to facilitate the detachment of the sludge attached to the mesh network 12.

Outside the casing 11, as shown in FIG. 1, the housing 13 prevents sludge from dewatering out of the rotating casing 11 and collects and discharges the dewatered water to the drain 26. The upper part of the housing 13 is provided with an air compressor 32 and an air injection pipe 33 as shown in FIGS. 1 and 5 to provide high pressure air to the through hole 23 of the casing 11. It is formed to detach the sludge adhering to the mesh network 12 by spraying.

The air injection pipes 33 are formed in parallel with a predetermined width over the length of the casing 11.

The injection tube 33 is provided with a solenoid valve 34 to be sprayed at regular intervals.

Example

According to the present invention, when a combustion gas passes through a desulfurizer (not shown) to desulfurize sulfur generated by combustion of a power plant, high-pressure, high-temperature steam and quicklime (CaO) powder are injected together inside the desulfurizer. Sulfur (S) and quicklime (CaO) react with steam (H ₂ O) at high temperature and high pressure to form calcined gypsum (CaS0 ₄ + 2H ₂ O), so that calcined gypsum (CaS0 ₄ + 2H ₂ O) captures sulfur (S) It is possible to remove sulfur from the combustion gas of the power plant, but there was a problem of contaminating water quality or soil by disposing waste water of sludged calcined gypsum (CaS0 ₄ + 2H ₂ O) in nature.

The present invention is to solve the above problems.

When the power 24 operates and the casing 11 rotates at 60 to 150 RPM, the sludge is rotated when the sludge is introduced by the sludge inlet 22 through the sludge inlet pipe 21. The mesh mesh 12 of the 200 mesh formed inside by the centrifugal force of the casing 11 and the inner surface of the casing 11 are rotated while being rotated to dehydrate the through-hole 23 of the casing 11 by the centrifugal force of the casing 11. Done.

When the above operation is continuous, the sludge forms a predetermined thickness in the mesh network 12, so that dehydration is not easy.

As described above, when the sludge is attached to the mesh network 12 by a predetermined thickness or more, the sludge 31 fixed to the end of the stirring furnace 29 of the stirrer 27 rotating inside the casing 11 is fixed. The sludge is detached by the sludge and the detached sludge is agitated by the stirring furnace 29 and is repeatedly attached to the mesh network 12 by the centrifugal force of the casing 11 to be dehydrated.

The sludge which is repeatedly dehydrated is dehydrated and caked and discharged while moving toward the outlet 25 by the stirring activity of the stirring furnace 29 and the taper portion 15 of the rotating casing 11.

Waste water to be dewatered is discharged through the through hole 23 perforated from the outer peripheral surface of the casing 11 to the inner peripheral surface.

As described above, the wastewater dewatered out of the casing 11 is scattered by the centrifugal force of the rotating casing 11.

As described above, the wastewater scattered from the casing 11 is prevented from being scattered by the housing 13 covered on the outer circumferential surface of the casing 11 and discharged into the wastewater outlet 26 formed at the lower portion of the housing 13.

When the incoming gypsum sludge is dehydrated for a long time in the casing 11, the dehydration effect is remarkably inferior because the through hole 23 of the mesh net 12 and the casing 11 is closed by sludge.

As described above, the air pressure provided from the air compressor 32 formed on the housing 13 is prevented from closing the through holes 23 of the mesh network 12 and the casing 11. It is sprayed on the outer circumferential surface of the casing 11 through the air nozzle 35 to detach the sludge attached to the through hole 23 and the mesh network 12 to the inner circumferential surface of the casing 11.

The injection of the air nozzle 35 is operated by the solenoid valve 34 formed in the air injection pipe 33 is continuously injected at a predetermined interval.

1 is an overall internal view of the dehydration apparatus according to the present invention

2 is a structural diagram of the casing

3 is an exploded view of the casing and the mesh network

4 is a cross-sectional view of the device according to the invention.

5 is a detail view of the stirrer and scraper;

6 is a detailed view of an air spray system

** Description of symbols for important parts of drawings **

11 casing 12 mesh network

13 housing 14 cylindrical part

15 taper portion 16 plate (a, b)

17 casing fixing bracket 18 bearing

19: bearing fixing bracket 21: sludge inlet pipe

22: sludge injection nozzle 23: through-hole

24: power 25: dewatered sludge outlet

26: outlet 27; agitator

28: stirrer rotating shaft 29: stirring furnace

31: scraper 32: air compressor

33: air injection pipe 34: solenoid valve

35: air nozzle 36: projection

37: blocking plate

Claims (4)

delete A casing 11 in which the cylindrical portion 14 and the taper portion 15 are fixed to the plates 16a and 16b, and a mesh net fixed to the inner surface of the casing 11 to rotate like the casing 11 (12), the sludge injection nozzle 22 for injecting and spraying gypsum sludge into the mesh network 12, and the sludge in the mesh network 12 is stirred and the mesh network 12 and the casing 11 inside Cover the outer circumferential surface of the casing (11) and the casing (11) for detaching the sludge attached to the surface and collect and discharge the dewatered water from the rotation of the casing (11), the air compressor 32 is mounted on the top of the compressor ( 32 is formed on the outer periphery of the casing (11) by spraying the air pressure generated in the housing 32, the air injection pipe 33 is formed to detach the sludge attached to the mesh network 12 and the through hole 23 of the casing 11 In the waste gypsum sludge dewatering device generated in the power plant wet desulfurization consisting of (13), K The casing 11 protrudes over its outer circumferential surface to form a plurality of through holes 23 between the projection 36 and the projection 36 and the projection 36 which provide tension to the casing 11. Waste gypsum sludge dewatering device generated from the wet desulfurization of the power plant, characterized in that the sludge is formed to be easily dewatered. According to claim 2, At the end of the stirring furnace 29 of the stirrer 27 formed over the inner length of the casing 11, a scraper 31 is formed in close proximity to the mesh network 12, the casing 11 The rotating gypsum sludge dewatering apparatus generated by the wet desulfurization of the power plant, characterized in that the rotating and rotating shaft 28 is configured to desorb the gypsum sludge attached to the mesh network (12). The air injection pipe (33) of the air compressor (32) installed in the housing (13) is exposed to the inside of the housing (13) and is formed close to the outer circumferential surface of the casing (11). Waste gypsum sludge dewatering device generated from the wet type desulfurization of the power plant, characterized in that the solenoid valve 34 is formed in the air injection pipe 33 so as to spray the casing 11 at regular intervals when it rotates.

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