CN111551044A - Electric furnace steelmaking ultrahigh-temperature flue gas purification and waste heat recovery system and method - Google Patents

Abstract

The invention discloses an electric furnace steelmaking ultra-high temperature flue gas purification and waste heat recovery system and method, which belong to the field of electric furnace flue gas waste heat recovery. The invention can ensure that the filter element works in a stable temperature range, prolong the service life of the purification device, improve the recovery efficiency of waste heat and reduce the waste of resources.

Description

Electric furnace steelmaking ultrahigh-temperature flue gas purification and waste heat recovery system and method

Technical Field

The invention relates to the field of electric furnace flue gas waste heat recovery, in particular to an electric furnace steelmaking ultrahigh-temperature flue gas purification and waste heat recovery system and method.

Background

The electric furnace smoke dust is metal smoke dust volatilized in the metal heating process, comprises metal and metal oxides, and the types of the metal and the metal oxides are related to various factors such as furnace charge components, oxidation materials, oil immersion materials, smelting speed, furnace temperature, oxygen blowing intensity and the like. The electric furnace smoke dust has the characteristics of small discharged smoke dust particles, high temperature and high toxicity (containing toxic substances such as dioxin, furan, heavy metals and the like), and if effective control measures are not taken, the electric furnace smoke dust can seriously pollute the environments of workshops and factories and influence the health of workers and surrounding residents.

Because of the application of the existing high-temperature flue gas filtration engineering, namely the long-term operation working environment of the filter bag, the high-temperature flue gas is generally cooled to be below about 200-250 ℃. Therefore, with reference to the division standard of the thermal power engineering, in the flue gas filtration industry, the flue gas to be filtered can be divided into normal temperature flue gas (<120 ℃), normal high temperature flue gas (<250 ℃), sub-high temperature flue gas (< 250-450 ℃), and ultra-high temperature flue gas (<800 ℃). The smoke which is generated in the electric furnace smelting process and passes through the fourth hole on the furnace cover, the combustion settling chamber and the water-cooling flue (about 1200 ℃) and comes out is defined as ultrahigh-temperature smoke.

At present, a quenching waste heat recovery device and a filtering and purifying device are adopted for smelting high-temperature flue gas by an electric furnace at home and abroad, but the following problems still exist: because the dust content of the electric furnace smelting high-temperature flue gas is high, the heated surface of the heat exchange element of the quenching waste heat recovery device is seriously accumulated with dust, and the heat exchange element is very difficult to remove, the dust content of the electric furnace smelting high-temperature flue gas is high, the heating surface of the heat exchange element of the quenching waste heat recovery device is seriously abraded, the heat exchange surface of the heat exchange element of the quenching waste heat recovery device is seriously washed, and the heat exchange area and the heat exchange efficiency cannot be effectively increased by adopting a fin structure form.

Disclosure of Invention

The invention aims to provide an electric furnace steelmaking ultra-high temperature flue gas purification and waste heat recovery system and method, which can enable a filter element to work in a relatively stable temperature range, prolong the service life of a purification device, improve the waste heat recovery efficiency and reduce the waste of resources.

The technical purpose of the invention is realized by the following technical scheme:

the utility model provides an electric stove steelmaking ultra-high temperature flue gas purification and waste heat recovery system, is including electric stove, first waste heat recovery device, ultra-high temperature flue gas constant temperature filtration purifier, second waste heat recovery device, heat exchanger, axial fan and the chimney that connects gradually, ultra-high temperature flue gas constant temperature filtration purifier is including last box, well box and the dust remover ash bucket that from top to bottom sets gradually, be provided with high temperature composite phase change heat storage stick in the well box, high temperature composite phase change heat storage stick is provided with two sets ofly along vertical direction, the intercommunication has waste heat recovery steam-water system on the first waste heat recovery device, waste heat recovery steam-water system passes through the pipeline respectively with second waste heat recovery device and heat exchanger intercommunication, it has into the mouth to open on the well box, it has the mouth of cigarette to open on the box.

Further, first waste heat recovery device is including the water-cooling sliding sleeve, burning deposit room and the vaporization cooling flue that connect in order, the exit end and the super high temperature flue gas constant temperature filter equipment's of vaporization cooling flue inlet section are connected.

Further, second waste heat recovery device is including preceding box, well case section and the back box that from top to bottom sets gradually, it has the flue gas entry to open preceding box upper end, well case section is provided with the heat pipe of taking the fin, the heat pipe is provided with a plurality of groups along vertical direction, back bottom half is provided with the exhanst gas outlet.

Furthermore, the inspection manhole door has been seted up on the preceding box, the inspection manhole door is provided with a plurality of at the middle box section, the intercommunication has the shock wave soot blowing pipe in the inspection manhole door, the shock wave soot blowing pipe is connected with outside driving system.

Further, the heat exchanger is in a fin heat exchange tube structure.

Furthermore, a water circulation cooling mode is adopted in the waste heat recovery steam-water system.

Further, a method for processing by using the system as described above comprises the following steps:

step S1: under the power action of an axial flow fan, ultra-high temperature flue gas generated in the electric furnace sequentially enters a water-cooling sliding sleeve and a vaporization cooling flue for primary cooling, and then enters a combustion settling chamber for dust precipitation;

step S2: the ultra-high temperature flue gas treated in the step (1) enters a vaporization cooling flue for secondary cooling, then enters an ultra-high temperature flue gas constant temperature filtering and purifying device, the temperature in the ultra-high temperature flue gas constant temperature filtering and purifying device is set to be 650 plus 800 ℃, and generated dust enters an ash hopper of a dust remover;

step S3: the ultra-high temperature flue gas processed in the step S2 enters a second waste heat recovery device and a heat exchanger, a plurality of groups of heat pipes in the second waste heat recovery device further cool the flue gas, and the heat exchanger is combined with a waste heat recovery steam-water system to further recover waste heat in the flue gas;

step S4: the flue gas processed in step S3 moves in the direction of the axial flow fan, and is then discharged through a chimney.

Further, the water-cooling sliding sleeve, the vaporization cooling flue, the second waste heat recovery device and the heat exchanger are communicated with a waste heat recovery steam-water system.

In conclusion, the invention has the following beneficial effects:

1. through the setting of ultra-high temperature flue gas constant temperature filtration purification device, realize that high temperature composite phase change heat accumulation stick absorbs and emits the heat through taking place the phase transition, ensure that the constancy of temperature in the device is in the high temperature section of settlement, effectively improve the life of the filter element in the device, realize having purified the flue gas in the high temperature section simultaneously, reduced the possibility of the production of toxicants such as dioxin/furan in the follow-up cooling process.

2. Through the setting of waste heat recovery soda system, the demineralized water is preheated to the heat energy of utilizing the recovery, has improved the utilization ratio of the energy.

Drawings

FIG. 1 is a schematic diagram of the overall structure for embodying the present invention in the embodiment;

FIG. 2 is an enlarged schematic structural view of a portion A of FIG. 1;

FIG. 3 is a schematic view of a partial structure used in the present invention in an embodiment;

fig. 4 is an enlarged schematic structural diagram for embodying the portion B in fig. 3 in the embodiment.

In the figure, 1, an electric furnace; 2. a first waste heat recovery device; 201. water-cooling the sliding sleeve; 202. a combustion settling chamber; 203. a vaporizing cooling flue; 3. an ultra-high temperature flue gas constant temperature filtering and purifying device; 301. an upper box body; 302. a middle box body; 303. a dust hopper of a dust collector; 4. a second waste heat recovery device; 401. a front box body; 402. a middle box section; 403. a rear box body; 5. a heat exchanger; 6. an axial flow fan; 7. a chimney; 8. a high-temperature composite phase-change heat storage rod; 9. a waste heat recovery steam-water system; 10. a smoke inlet; 11. a smoke outlet; 12. a flue gas inlet; 13. a flue gas outlet; 14. a manhole door is overhauled; 15. a shock wave lance tube; 901. a high pressure steam drum; 902. a heat accumulator; 903. a water diversion header; 904. a low pressure steam drum; 905. a deaerator; 906. the deaerator is connected with a soft water tank; 907. a booster pump.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

In which like parts are designated by like reference numerals. It should be noted that the terms "front," "back," "left," "right," "upper" and "lower" used in the following description refer to directions in the drawings, and the terms "bottom" and "top," "inner" and "outer" refer to directions toward and away from, respectively, the geometric center of a particular component.

Example (b):

an electric furnace 1 steel-making ultra-high temperature flue gas purification and waste heat recovery system is shown in figures 1 and 2 and comprises an electric furnace 1, a first waste heat recovery device 2, an ultra-high temperature flue gas constant temperature filtering and purifying device 3, a second waste heat recovery device 4, a heat exchanger 5, an axial flow fan 6 and a chimney 7 which are connected in sequence. Ultra-high temperature flue gas constant temperature filtration purification device 3 is provided with high-temperature composite phase change heat accumulation stick 8 including last box 301, well box 302 and the dust remover ash bucket 303 that from top to bottom sets gradually in the well box 302, and high-temperature composite phase change heat accumulation stick 8 is provided with two sets ofly along vertical direction, adopts the ceramic filter tube to purify the dust in the ultra-high temperature flue gas constant temperature filtration purification device 3 simultaneously. The first waste heat recovery device 2 is communicated with a waste heat recovery steam-water system 9, the waste heat recovery steam-water system 9 is communicated with the second waste heat recovery device 4 and the heat exchanger 5 through pipelines respectively, the middle box body 302 is provided with a smoke inlet 10, the upper box body 301 is provided with a smoke outlet 11, and the heat exchanger 5 is of a fin heat exchange tube structure, so that the heat dissipation efficiency is improved.

As shown in fig. 1, the first waste heat recovery device 2 is provided and includes a water-cooling sliding sleeve 201, a combustion settling chamber 202 and a vaporization cooling flue 203 which are connected in sequence, the vaporization cooling flue 203 is connected to both sides of the combustion settling chamber 202, and the outlet end of the vaporization cooling flue 203 is connected to the inlet section of the ultra-high temperature flue gas constant temperature filtering device.

As shown in fig. 1 and 2, under the driving action of the axial flow fan 6, the ultra-high temperature flue gas in the electric furnace 1 firstly enters the vaporization cooling flue 203 through the water-cooling sliding sleeve 201, and then enters the next vaporization cooling flue 203 through the combustion settling chamber 202, so as to further recover heat in the ultra-high temperature flue gas. Then the ultra-high temperature flue gas enters the ultra-high temperature flue gas constant temperature filtering and purifying device 3 through the smoke inlet 10, the temperature in the ultra-high temperature flue gas constant temperature filtering and purifying device 3 is set to be 650 plus 800 ℃, and the ultra-high temperature flue gas is converted into high temperature flue gas to be discharged through the action of the ceramic filter tube and the high temperature composite phase change heat storage rod 8. The high-temperature flue gas continues to move to the second waste heat recovery device 4 and the heat exchanger 5 under the action of the axial flow fan 6, further cools and consumes heat in the high-temperature flue gas through the second waste heat recovery device 4 and the heat exchanger 5, and then is discharged from the chimney 7.

As shown in fig. 2, in order to improve the recovery of the heat in the flue gas by the second waste heat recovery device 4, the second waste heat recovery device 4 includes a front box 401, a middle box 402 and a rear box 403, which are sequentially arranged from top to bottom. The shell of the second waste heat recovery device 4 is of a membrane type water-cooled wall structure, the upper end of a front box body 401 is provided with a flue gas inlet 12, a middle box section 402 is provided with heat pipes with fins, the heat pipes are inserted into the middle box section 402 from outside, five groups of heat pipes are arranged in the vertical direction, and an alloy coating is sprayed on the surfaces of the heat pipes. The bottom of the rear box 403 is provided with a smoke outlet 13. Through the arrangement of five groups of heat pipes with fins, the heating area is increased, and the quenching effect of the heat pipes on high-temperature flue gas is improved.

As shown in fig. 3 and 4, the front box 401 is provided with four manhole doors 14, the number of the manhole doors 14 is four in the middle box section 402, one manhole door 14 is arranged between two groups of heat pipes, and meanwhile, the front box 401 is also provided with the manhole door 14. A shock wave soot blowing pipe 15 is communicated with the inside of the manhole door 14, and the shock wave soot blowing pipe 15 is connected with an external power system. When in high-temperature flue gasContaining CO or H₂When the gas is explosive, the nitrogen gas can be blown into the second waste heat recovery device 4 through the shock wave soot blowing pipe 15, so that the possibility of explosion is reduced.

As shown in fig. 1, the waste heat recovery steam-water system 9 is communicated with the water-cooling sliding sleeve 201, the vaporization cooling flue 203, the second waste heat recovery device 4 and the heat exchanger, a high-pressure steam drum 901, a heat accumulator 902, a water diversion header tank 903, a low-pressure steam drum 904 and a deaerator 905 are connected to the waste heat recovery steam-water system 9 through pipelines, the deaerator 905 is connected with a soft water tank 906, the soft water tank 906 is communicated with the heat exchanger 5, the heat exchanger 5 is simultaneously communicated with an external soft water pool, the heat exchanger 5 can effectively recover waste heat in smoke at a temperature of 200 ℃ or lower, then the soft water is preheated by recovered heat energy, and the pipeline connected with the soft water tank 906, the deaerator 905 and the water diversion header tank 903 is communicated with a pressure.

The invention also discloses a method for processing by adopting the system, which comprises the following steps:

step S1: under the power action of the axial flow fan 6, ultra-high temperature flue gas generated in the electric furnace 1 sequentially enters the water-cooling sliding sleeve 201 and the vaporization cooling flue 203 for primary cooling, the water-cooling sliding sleeve 201 and the vaporization cooling flue 203 are both communicated with the waste heat recovery steam-water system 9, and then enters the combustion settling chamber 202 for dust precipitation;

step S2: the ultra-high temperature flue gas treated in the step (1) enters a vaporization cooling flue 203 for secondary cooling, then enters an ultra-high temperature flue gas constant temperature filtering and purifying device 3, the temperature in the ultra-high temperature flue gas constant temperature filtering and purifying device 3 is set to be 650 plus-800 ℃, the high-temperature composite phase-change heat storage rod 8 can absorb and release heat according to the temperature of the entering ultra-high temperature flue gas, the ultra-high temperature flue gas is converted into high-temperature flue gas to be discharged, and meanwhile, absorbed dust enters a dust hopper 303 of a dust remover;

step S3: the ultra-high temperature flue gas processed in the step S2 enters the second waste heat recovery device 4 and the heat exchanger 5, the flue gas is further cooled by a plurality of groups of heat pipes in the second waste heat recovery device 4, and the heat exchanger 5 further recovers waste heat in the flue gas by combining with the waste heat recovery steam-water system 9;

step S4: the flue gas processed in step S3 moves in the direction of the axial flow fan 6, and is then discharged through the chimney 7.

The specific implementation process comprises the following steps: under the action of the axial flow fan 6, the ultra-high temperature flue gas generated in the electric furnace 1 is primarily cooled through the water-cooling sliding sleeve 201 and the vaporization cooling flue 203, and then enters the combustion settling chamber 202 for dust precipitation. And then the temperature is secondarily reduced through the vaporization cooling flue 203, and then the smoke enters the ultra-high temperature smoke constant temperature filtering and purifying device 3 for cooling, the temperature in the ultra-high temperature smoke constant temperature filtering and purifying device 3 is set to be 650 plus 800 ℃, and the generated dust enters the dust hopper 303 of the dust remover. The discharged flue gas enters the second waste heat recovery device 4 and the heat exchanger 5 for cooling, meanwhile, the heat exchanger 5 is combined with a waste heat recovery steam-water system 9 to further recycle the waste heat in the flue gas, and the purified flue gas is discharged from a chimney 7 through an axial flow fan 6.

The present embodiment is only for explaining the present invention, and it is not limited to the present invention, and those skilled in the art can make modifications of the present embodiment without inventive contribution as needed after reading the present specification, but all of them are protected by patent law within the scope of the claims of the present invention.

Claims (8)

1. The utility model provides an electric stove steelmaking superhigh temperature gas cleaning and waste heat recovery system which characterized in that: the device comprises an electric furnace (1), a first waste heat recovery device (2), an ultra-high temperature flue gas constant temperature filtering and purifying device (3), a second waste heat recovery device (4), a heat exchanger (5), an axial flow fan (6) and a chimney (7) which are sequentially connected, wherein the ultra-high temperature flue gas constant temperature filtering and purifying device (3) comprises an upper box body (301), a middle box body (302) and a dust remover ash hopper (303) which are sequentially arranged from top to bottom, high-temperature composite phase change heat storage rods (8) are arranged in the middle box body (302), the high-temperature composite phase change heat storage rods (8) are arranged in two groups along the vertical direction, a waste heat recovery steam-water system (9) is communicated with the first waste heat recovery device (2), the waste heat recovery steam-water system (9) is respectively communicated with the second waste heat recovery device (4) and the heat exchanger (5) through pipelines, a smoke inlet (, the upper box body (301) is provided with a smoke outlet (11).

2. The electric steelmaking ultra-high temperature flue gas purification and waste heat recovery system of claim 1, characterized in that: the first waste heat recovery device (2) comprises a water-cooling sliding sleeve (201), a combustion settling chamber (202) and a vaporization cooling flue (203) which are sequentially connected, and the outlet end of the vaporization cooling flue (203) is connected with the inlet section of the ultra-high temperature flue gas constant temperature filtering device.

3. The electric steelmaking ultra-high temperature flue gas purification and waste heat recovery system of claim 1, characterized in that: second waste heat recovery device (4) are including preceding box (401), well case section (402) and back box (403) that from top to bottom set gradually, open preceding box (401) upper end has flue gas entry (12), well case section (402) are provided with the heat pipe of taking the fin, the heat pipe is provided with a plurality of groups along vertical direction, back box (403) bottom is provided with exhanst gas outlet (13).

4. The electric steelmaking ultra-high temperature flue gas purification and waste heat recovery system of claim 3, characterized in that: preceding box (401) are last to have seted up inspection manhole door (14), inspection manhole door (14) are provided with a plurality of in well case section (402), the intercommunication has shock wave soot blowing pipe (15) in inspection manhole door (14), shock wave soot blowing pipe (15) are connected with outside driving system.

5. The electric steelmaking ultra-high temperature flue gas purification and waste heat recovery system of claim 1, characterized in that: the heat exchanger (5) is in a fin heat exchange tube structure.

6. The electric steelmaking ultra-high temperature flue gas purification and waste heat recovery system of claim 1, characterized in that: and a water circulation cooling mode is adopted in the waste heat recovery steam-water system (9).

7. A method of processing using the system of claim 1, comprising the steps of:

step S1: under the power action of an axial flow fan (6), ultrahigh-temperature flue gas generated in an electric furnace (1) sequentially enters a water-cooling sliding sleeve (201) and a vaporization cooling flue (203) for primary cooling, and then enters a combustion settling chamber (202) for dust precipitation;

step S2: the ultra-high temperature flue gas treated in the step (1) enters a vaporization cooling flue (203) for secondary cooling, then enters an ultra-high temperature flue gas constant temperature filtering and purifying device (3), the temperature in the ultra-high temperature flue gas constant temperature filtering and purifying device (3) is set to be 650 plus 800 ℃, and generated dust enters a dust hopper (303) of a dust remover;

step S3: the ultra-high temperature flue gas processed in the step S2 enters a second waste heat recovery device (4) and a heat exchanger (5), a plurality of groups of heat pipes in the second waste heat recovery device (4) further cool the flue gas, and the heat exchanger (5) further recovers waste heat in the flue gas by combining a waste heat recovery steam-water system (9);

step S4: the flue gas processed in step S3 moves in the direction of the axial flow fan (6), and is then discharged through the chimney (7).

8. The electric steelmaking superhigh temperature flue gas purification method as set forth in claim 7, characterized in that: the water-cooling sliding sleeve (201), the vaporization cooling flue (203), the second waste heat recovery device (4) and the heat exchanger are communicated with a waste heat recovery steam-water system (9).

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