KR20120081914A - RECYCLING SYSTEM FOR SPENT CATALYST OF DE-NOx EQUIPMENT - Google Patents

Abstract

PURPOSE: A system for regenerating waste catalysts from Selective Catalytic Reduction(SCR) denitrification facilities is provided to save costs required for washing processes by efficiently washing the waste catalysts based on simple facilities. CONSTITUTION: A system for regenerating waste catalysts from SCR denitrification facilities includes a multi-functional continuous washing bath(100), a rinsing bath(300), a vanadium precipitating bath(500), and a gas drying furnace(B). The multi-functional continuous washing bath includes a housing. Washing liquid is stored in the multi-functional continuous washing bath. Waste catalysts(10) are immerged in the washing liquid and washed. The rinsing bath rinses the washed waste catalysts. The rinsed waste catalysts are immersed in the vanadium precipitating bath to coat a vanadium coating agent on the surfaces of the rinsed waste catalysts. The gas drying furnace dries the coated waste catalysts.

Description

SCR denitrification equipment waste catalyst regeneration system {RECYCLING SYSTEM FOR SPENT CATALYST OF DE? NOx EQUIPMENT}

The present invention relates to a multifunctional continuous washing tank for washing waste catalyst used in an SCR denitrification system and a recycling system of waste catalyst using the same.

NOx (nitrogen oxide) is a serious air pollutant, and there is an increasing demand for technology that reduces its emission or removes it from the gas and releases it to the atmosphere. The NOx removal technology has been studied for a long time, and among them, the catalytic selective catalytic reduction (SCR) is used as the most effective technology.

In such an SCR denitrification system, a mixture of titanium or vanadium oxide is used as a catalyst, and by-products are attached to the surface of the porous catalyst in the process of reducing NOx by such a catalyst. Therefore, in order to regenerate such expensive spent catalyst, a process of washing the surface of the catalyst and recoating the vanadium compound is required.

10 is a view showing a catalyst used in such an SCR denitrification system. The catalyst 10 of the SCR denitrification facility has a shape in which a plurality of holes 12 in the longitudinal direction are formed as shown in FIG. Oxide).

However, in the conventional technology of regenerating the waste catalyst after the use of such a catalyst, the spent catalyst is suspended on the top and washed, and the pore inside thereof also needs to be washed. Generally, the washing is performed through 7 to 8 processes. There was a troublesome work by carrying out and then carrying out the coating.

In addition, since the washing equipment itself consists of a plurality of large appliances, the cost of the washing equipment is very high, and the washing process is not efficient, and thus, accessibility to the recycling of the waste catalyst itself is inferior.

Specifically, the regeneration of the conventional SCR denitrification equipment waste catalyst is generally subjected to chemical regeneration by immersing the spent catalyst in general water for a long time and immersing it in a container containing chemicals for a long time. However, this regeneration method is time-consuming and the efficiency of washing and regeneration very low, there was a difficult side to be realized. Therefore, there is an urgent need for a technique that can efficiently reduce the recycling process of the waste catalyst and significantly reduce the washing time and the regeneration time through physical washing.

The matters described as the background art are only for the purpose of improving the understanding of the background of the present invention, and should not be taken as acknowledging that they correspond to the related art already known to those skilled in the art.

The present invention has been proposed to solve this problem, and can efficiently perform the cleaning of the spent catalyst, and also modularize the overall regeneration equipment to increase the efficiency of regeneration while the installation of the equipment is not cumbersome to move SCR Its purpose is to provide a regeneration system for a denitrification plant waste catalyst.

Regeneration system of SCR denitrification equipment waste catalyst according to the present invention for achieving the above object, the housing is provided, the cleaning liquid is stored therein, the waste catalyst is immersed in the cleaning liquid and the waste catalyst is reciprocated by the moving part A multifunctional continuous wash bath to be cleaned; A washing tank for washing the washed waste catalyst with a washing liquid; A vanadium impregnation tank for immersing the washed waste catalyst to coat a vanadium coating on a surface thereof; And a gas drying furnace for heating and drying the coated waste catalyst.

In addition, the SCR denitrification equipment waste catalyst regeneration system of the present invention may further include a waste heat drying rack for drying the cleaned waste catalyst using waste heat from a gas drying furnace.

The waste heat drying rack may be configured of a hot air discharge unit coupled to the moving unit to supply hot air to the waste catalyst side below and a supply pipe for transferring waste heat from the gas drying furnace to the hot air discharge unit.

In addition, the SCR denitrification system waste catalyst regeneration system of the present invention receives the wastewater from any one or more of the multifunctional continuous washing tank, washing tank and vanadium impregnation tank and then filtered through a filter to store the filtered wastewater in the housing and the waste catalyst is It may further include a pre-wash bath to be immersed in the filtered waste water of the housing.

The multifunctional continuous washing tank, the housing in which the cleaning liquid is stored; And a moving part provided at an upper side of the housing and having a catalyst coupled to a lower end such that a hole of the waste catalyst formed in a longitudinal direction is disposed in the vertical direction, and having a cylinder so as to vertically reciprocate the waste catalyst in a state immersed in the housing. It may include.

In addition, the SCR denitrification equipment waste catalyst regeneration system of the present invention may further include a test table for inspecting whether the pores of the waste catalyst is sufficiently washed by illuminating light from the washed down waste catalyst.

In addition, the regeneration system of the SCR denitrification equipment waste catalyst of the present invention may further include a hoist trail for fixing the waste catalyst and sequentially moving the waste catalyst to a multifunctional continuous washing tank, a washing tank, a vanadium impregnation tank, and a gas drying furnace. have.

The cleaning tank includes a housing in which the cleaning liquid is stored, a moving part provided above the housing to selectively couple and move the waste catalyst selectively, a bubbling part provided below the housing to apply bubbles to the waste catalyst in the cleaning liquid, and inside the cleaning liquid. It may include an ultrasound unit for generating an ultrasound.

The vanadium impregnation tank is provided in a housing in which the vanadium coating liquid is stored, a moving part for selectively coupling and moving up and down the waste catalyst, a heating part for heating the vanadium coating liquid inside the housing, and a lower portion of the housing to the waste catalyst side. It may include an aerator for generating bubble flow.

According to the regeneration system of the SCR denitrification equipment waste catalyst having the above-described structure, the waste catalyst can be washed sufficiently efficiently even with a relatively simple equipment, thereby reducing the cleaning cost and facilitating installation and maintenance of the system.

In addition, each configuration is configured to be movable to facilitate installation and maintenance, and to improve the accessibility of the consumer to the denitrification facility.

In addition, the denitrification time is significantly shortened to improve the production efficiency of the regenerated catalyst.

1 is a view showing a regeneration system of SCR denitrification equipment waste catalyst according to an embodiment of the present invention.
FIG. 2 is a view showing an atmospheric portion of a regeneration system of an SCR denitrification plant waste catalyst shown in FIG. 1.
Figure 3 is a view showing a multifunctional continuous washing tank of the regeneration system of the SCR denitrification equipment waste catalyst shown in FIG.
Figure 4 is a view showing the inspection table of the regeneration system of the SCR denitrification equipment waste catalyst shown in FIG.
5 is a view showing a cleaning tank of a regeneration system of the SCR denitrification equipment waste catalyst shown in FIG.
6 is a view showing the waste heat drying rack of the regeneration system of the SCR denitrification equipment waste catalyst shown in FIG. 1.
7 is a view showing a vanadium impregnation tank of the regeneration system of the SCR denitrification equipment waste catalyst shown in FIG. 1.
FIG. 8 is a view illustrating an inlet side of a gas drying furnace of a regeneration system of an SCR denitrification plant waste catalyst shown in FIG. 1;
9 is a view showing a gas drying furnace of the regeneration system of the SCR denitrification equipment waste catalyst shown in FIG.
10 is a view showing a conventional SCR denitrification catalyst.

Hereinafter, with reference to the accompanying drawings looks at the multifunctional continuous washing tank of the SCR denitrification equipment waste catalyst according to a preferred embodiment of the present invention and a waste catalyst regeneration system using the same.

1 is a view showing a regeneration system of SCR denitrification equipment waste catalyst according to an embodiment of the present invention. Regeneration system of SCR denitrification equipment waste catalyst is composed of washing container (A) and drying container (B, gas drying furnace), and waste catalyst (10) between each container and container is automatically along hoist trail (H). Is moved to. In addition, each of these containers (A, B) is basically configured to be movable so that it is possible to install and move in a small workplace and easy to maintain.

Cleaning container (A) may be largely composed of the atmospheric, multi-functional continuous washing tank 100, the inspection table 200, the washing tank 300, waste heat drying rack 400, vanadium impregnation tank (500). An important configuration is provided above the housing 120, the housing 120, the cleaning solution is stored, the waste catalyst 10 is coupled to the lower end of the cylinder 640 is provided so that the waste catalyst 10 is immersed in the housing 120 In the lower part of the vibrator 660 and the housing 120 coupled to the moving part 600 and the waste catalyst 10 to provide a vibration to the waste catalyst 10 in order to vertically reciprocate in a closed state. It includes a bubbling portion 140 for applying a bubble to the catalyst 10 side.

The waste catalyst 10 washed in the washing container A is completely repacked and delivered after the water is dried in the gas drying furnace of the drying container B.

2 is a view showing the waiting portion, a cylinder 640 is installed at the lower end of the hoist trail (H) and the holder 620 is installed on the cylinder 640, the waste catalyst 10 is fixed through the holder 620 And move. The spent catalyst 10 is moved and seated by a forklift to the guide 2 formed of a grating structure. The cylinder 640 extends toward the waste catalyst 10 seated on the guide 2 and fixes the upper end of the waste catalyst 10 to a fixed base. Thereafter, the cylinder 640 is contracted to lift the waste catalyst 10, and the waste catalyst 10 is transferred to the next process by using the hoist trail H.

3 is a view showing a multifunctional continuous washing tank which is the next process. Multifunctional continuous washing tank, the housing 120 in which the washing liquid is stored; A moving part provided above the housing 120 to couple the waste catalyst 10 to a lower end thereof, wherein a cylinder 640 is provided to allow the waste catalyst 10 to reciprocate up and down in a state of being immersed in the housing 120 ( 600); A vibrator 660 coupled to the spent catalyst 10 to provide its own vibration to the spent catalyst 10; And a bubbling unit 140 provided below the housing 120 to apply bubbles to the waste catalyst 10 in the cleaning solution.

Here, the moving part 600, the hoist trail (H) for horizontal movement, the cylinder 640 provided in the lower portion of the hoist trail (H) for vertical movement, the waste catalyst holder coupled to the lower end of the cylinder (640) ( 620 is as described above.

In addition, the inside of the housing 120 is provided with a guide 160 on which the immersed waste catalyst 10 is seated and an elastic buffer 180 positioned between the guide 160 and an inner wall of the housing 120, and the guide 160 may be formed of a grating structure.

Specifically, the multifunctional continuous washing tank 100 is installed in the housing 120 below the moving line of the waste catalyst (10). The cleaning liquid is obtained and stored in the housing 120 through the inlet part S, and the cleaning liquid is discharged through the drain D after the cleaning. The waste catalyst 10 is lowered and immersed in the washing liquid stored in the housing 120 in a state where the waste catalyst 10 is fixed to the holder 620 according to the extension of the cylinder 640. On the other hand, the lower portion of the housing 120 is provided with a nozzle-type bubbling portion 140 to which bubbles are supplied, and a guide 160 having a grating structure is provided thereon. The waste catalyst 10 is seated on the guide 160 as it descends. In addition, the elastic buffer 180 is installed between the guide 160 and the inner wall of the housing 120, the elastic buffer 180 is configured to be a strong spring.

Describing the washing operation process, the bubbling portion 140 at the lower side generates a high pressure bubble, and the bubble passes through the guide 160 of the grating structure and enters the pores of the spent catalyst to drop impurities contained in the pores. Do it. In addition, the waste catalyst 10 is continuously shaken up and down inside the cleaning liquid by the vertical reciprocating motion of the cylinder 640, whereby the residue of the waste catalyst is dispersed into the cleaning liquid and falls out. In addition, since the guide 160 is supported by the spring 180, the cushioning is performed so that the equipment does not become excessive during the reciprocating motion of the cylinder 640, and the elastic force is applied to the vertical motion to increase the washing effect.

On the other hand, a plurality of vibrators 660 are spaced apart on the upper part of the fixing stand 620 to apply the vibration to the fixing stand 620, which is directly transmitted to the waste catalyst 10, the waste catalyst 10 to the magnetic vibration Make the dregs come off by

FIG. 4 is a view illustrating an inspection table of a regeneration system of the SCR denitrification plant waste catalyst illustrated in FIG. 1, wherein the waste catalyst 10 that has passed through the washing tank is lifted by the cylinder 640 and is placed along the hose trail H. Is transferred to). The inspection table is to illuminate the light under the washed waste catalyst 10 so as to inspect whether the pores of the waste catalyst 10 are sufficiently washed.

In detail, the inspection table 200 includes a guide 220 having a grating structure in which the waste catalyst 10 is lowered by the cylinder 640 and a plurality of lighting units 240 that provide light from the guide 220. It includes. When the light is illuminated from below, the light passes through the grating structure and the light passes through the pores of the washed waste catalyst 10. The degree of washing of the waste catalyst 10 can be checked based on the transmission of light. If the washing is successful, the process proceeds to the next step. If the washing is not performed, the washing process is reversed through the hoist trail (H). It will go through.

5 is a view showing a cleaning tank of a regeneration system of the SCR denitrification equipment waste catalyst shown in FIG. 1. The washing tank is to wash the washed waste catalyst 10 with a washing liquid, and to wash away the foreign matter and the washing liquid attached to the surface of the waste catalyst. Therefore, various embodiments may be possible, but the cleaning liquid is preferably composed of pure water only.

The cleaning tank 300 is provided above the housing 320 and the housing 320 in which the cleaning liquid is stored, and the moving part 600 and the housing 320 for selectively coupling and moving the waste catalyst 10 up and down. It is provided in the lower portion to include a bubbling portion 340 for applying bubbles to the waste catalyst 10 side in the cleaning liquid and the ultrasonic portion 390 for generating ultrasonic waves in the cleaning liquid.

The guide 360 of the cleaning tank 300 is also formed of a grating structure and supported by the spring 380. In addition, between the pores of the waste catalyst 10 is washed by the high-pressure bubble of the bubbling portion 340, the ultrasonic portion 390 is provided on both sides of the housing in the cleaning solution to wash the foreign substances of the waste catalyst 10 To me. In addition, it is similarly introduced into the inlet S 'connected to the housing 320 of the cleaning liquid and discharged to the drain D'. The cleaned waste catalyst 10 finishes the cleaning by raising the cylinder 640, and is moved to the next process by the hoist trail H.

6 is a view showing a waste heat drying rack of the regeneration system of the SCR denitrification equipment waste catalyst shown in FIG. 1, and FIG. 7 is a view showing a vanadium impregnation tank of the regeneration system of the SCR denitrification equipment waste catalyst shown in FIG.

Waste heat drying rack 400 is to dry the washed waste catalyst 10 using the waste heat of the gas drying furnace (B), coupled to the moving unit 600 to supply hot air to the waste catalyst 10 side of the lower side The hot air discharge unit 440 and the supply pipe 460 for transferring waste heat from the gas drying furnace (B) to the hot air discharge unit 440.

The guide 420 of the grating structure is provided below, and the waste catalyst 10 is seated on the guide 420. In addition, the hot air discharge unit 440 is installed on the fixed stand 620 of the moving unit 600 and the hot air of the hot air discharge unit 440 passes through the fixed stand 620 to blow out the waste catalyst 10. . The supply pipe 460 from the gas drying furnace B is connected to the hot air discharge part 440 to use the waste heat of the gas drying furnace B later. Through this, the washed waste catalyst 10 is efficiently dried.

The cleaning liquid which is separated by the hot air from the waste catalyst 10 falls to the bottom through the hole of the grating structure.

Thereafter, the spent catalyst 10 undergoes a recoating process. The vanadium impregnation tank 500 is to coat the vanadium coating on the surface by immersing the dried waste catalyst 10, the housing 520, the vanadium coating liquid is stored is provided above the housing 520 and the waste catalyst 10 It is provided in the moving unit 600 to selectively combine and move up and down, the heating unit 580 for heating the vanadium coating liquid in the housing 520 and the lower portion of the housing 520 to generate bubble flow to the waste catalyst 10 side An aerator 540.

The spent catalyst 10 moved by the hoist trail H is lowered by the extension of the cylinder 640. The vanadium coating liquid is stored in the housing 520, and the waste catalyst 10 is impregnated with the coating liquid. The waste catalyst is lowered and seated on the guide 560 of the grating structure, and the vanadium coating liquid as the bubble flow generated by the aerator 540 (aerator, detonator) below the guide 560 rises up the waste catalyst 10. To coat between the pores of the spent catalyst 10. In addition, a heating unit 580 is provided inside the housing 520 to maintain the vanadium coating liquid at an appropriate temperature, and a thermometer 590 is provided to maintain the coating liquid at 30 to 40 ° C. Such coating liquid is introduced into the housing 520 through the inlet S ″ and discharged through the drain D ″.

The spent catalyst 10 after the recoating is completed is transferred to the inlet side of the drying furnace B by the hoist trail H.

On the other hand, although not shown, after receiving the wastewater from any one or more of the multi-function continuous washing tank 100, the washing tank 300 and the vanadium impregnation tank 500 and filtered through a filter to store the filtered wastewater in the housing It is also possible to further include a preliminary washing tank for the waste catalyst 10 to be immersed in the filtered waste water of the housing.

The preliminary washing tank allows the waste catalyst to be immersed in the recycled wastewater for a long time in the preliminary step of the multifunctional continuous washing tank of the present invention, and at the same time, it is possible to easily recycle the wastewater in a short time. The preliminary washing tank may be provided with a bubbling portion to allow the waste catalyst to be washed better by the waste water.

FIG. 8 is a view illustrating a gas drying furnace inlet side of the regeneration system of the SCR denitrification waste catalyst shown in FIG. 1, and FIG. 9 is a view illustrating a gas drying furnace of the regeneration system of the SCR denitrification waste catalyst shown in FIG. 1. .

Gas drying furnace (B) is composed of a container to heat-dry the coated waste catalyst 10, the waste catalyst 10 is seated on the guide rail 760 on the ground and the holder 620 is separated. Then, the spent catalyst 10 is moved forward along the guide rail 760, the heating air introduced through the air heater 710 and the blower 720 of the drying furnace (B) by the duct 730 The discharge port 740 is distributed to fill the interior of the gas drying furnace B with high temperature and high pressure air. The waste catalyst 10 is dried while moving to the guide rail 760 in the interior of the drying furnace. In addition, as described above, some of the hot air of the gas drying furnace (B) is to be transferred to the waste heat drying rack 400 through the supply pipe (460).

While the present invention has been particularly shown and described with reference to specific embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the following claims It will be apparent to those of ordinary skill in the art.

10: waste catalyst 100: multifunctional continuous washing tank
120 housing 300 washing tank
400: waste heat drying rack 500: vanadium impregnation tank
600: moving part B: gas drying furnace

Claims (9)

Multifunctional continuous washing tank 100 is provided with a housing 120, the washing liquid is stored therein, the waste catalyst 10 is immersed in the washing liquid and the waste catalyst 10 is reciprocated by the moving part 600 to be washed. ;
A washing tank 300 for washing the washed waste catalyst 10 with a washing liquid;
A vanadium impregnation tank 500 for dipping the cleaned waste catalyst 10 to coat a vanadium coating agent on a surface thereof; And
And a gas drying furnace (B) for heating and drying the coated waste catalyst (10). The method according to claim 1,
And a waste heat dryer (400) for drying the cleaned waste catalyst (10) using waste heat from a gas drying furnace (B). The method according to claim 2,
The waste heat drying rack 400 is coupled to the moving part 600 from the gas drying furnace (B) to the hot air discharge unit 440 and the hot air discharge unit 440 for supplying hot air to the waste catalyst 10. SCR denitrification equipment waste catalyst regeneration system, characterized in that consisting of a feed pipe for transporting waste heat. The method according to claim 1,
Wastewater is supplied from any one or more of the multifunctional continuous washing tank 100, the washing tank 300, and the vanadium impregnation tank 500, filtered through a filter, and the filtered wastewater is stored in a housing, and the waste catalyst 10 is housed. Regeneration system of the SCR denitrification equipment waste catalyst further comprising a; preliminary washing tank to be immersed in the filtered waste water. The method according to claim 1,
The multifunctional continuous washing tank 100, the housing 120 in which the washing liquid is stored; And a catalyst is coupled to the lower end and the cylinder 640 is disposed so that the holes of the spent catalyst formed in the longitudinal direction are disposed above the housing 120 and are disposed in the vertical direction, and the waste catalyst 10 is immersed in the housing 120. Multifunctional continuous washing tank of the SCR denitrification facility waste catalyst comprising a; moving unit 600 to reciprocate up and down in the state. The method according to claim 1,
SCR denitrification facility waste catalyst, characterized in that it further comprises; an inspection table 200 for inspecting whether the pores of the waste catalyst 10 is sufficiently washed by illuminating light from the washed waste catalyst (10) Regeneration system. The method according to claim 1,
The waste catalyst 10 is fixed, and a hoist trail for sequentially moving the waste catalyst 10 to the multifunctional continuous washing tank 100, the washing tank 300, the vanadium impregnation tank 500, and the gas drying furnace (B). (H); SCR denitrification equipment waste catalyst regeneration system further comprising. The method according to claim 1,
The cleaning tank 300 is provided above the housing 320 and the housing 320 in which the cleaning liquid is stored, and the moving part 600 and the housing 320 for selectively coupling and moving the waste catalyst 10 up and down. SCR denitrification equipment waste catalyst regeneration system, characterized in that it comprises a bubbling unit 340 provided in the lower portion to apply bubbles to the waste catalyst (10) in the cleaning liquid and the ultrasonic portion (390) for generating ultrasonic waves inside the cleaning liquid. The method according to claim 1,
The vanadium impregnation tank 500 is provided above the housing 520 and the housing 520 in which the vanadium coating liquid is stored, and the moving part 600 and the housing 520 for selectively coupling and moving the waste catalyst 10 up and down. SCR denitrification equipment waste catalyst, characterized in that it comprises a heating unit 580 for heating the vanadium coating liquid therein and an aerator 540 provided in the lower portion of the housing 520 to generate bubble flow to the waste catalyst 10 side. Regeneration system.

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