EP1854866A1 - Temperature raising furnace door for coke carbonization furnace - Google Patents
Temperature raising furnace door for coke carbonization furnace Download PDFInfo
- Publication number
- EP1854866A1 EP1854866A1 EP06714090A EP06714090A EP1854866A1 EP 1854866 A1 EP1854866 A1 EP 1854866A1 EP 06714090 A EP06714090 A EP 06714090A EP 06714090 A EP06714090 A EP 06714090A EP 1854866 A1 EP1854866 A1 EP 1854866A1
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- EP
- European Patent Office
- Prior art keywords
- air
- check valve
- valve plate
- air supply
- chamber unit
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- C—CHEMISTRY; METALLURGY
- C10—PETROLEUM, GAS OR COKE INDUSTRIES; TECHNICAL GASES CONTAINING CARBON MONOXIDE; FUELS; LUBRICANTS; PEAT
- C10B—DESTRUCTIVE DISTILLATION OF CARBONACEOUS MATERIALS FOR PRODUCTION OF GAS, COKE, TAR, OR SIMILAR MATERIALS
- C10B25/00—Doors or closures for coke ovens
- C10B25/02—Doors; Door frames
- C10B25/06—Doors; Door frames for ovens with horizontal chambers
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- C—CHEMISTRY; METALLURGY
- C10—PETROLEUM, GAS OR COKE INDUSTRIES; TECHNICAL GASES CONTAINING CARBON MONOXIDE; FUELS; LUBRICANTS; PEAT
- C10B—DESTRUCTIVE DISTILLATION OF CARBONACEOUS MATERIALS FOR PRODUCTION OF GAS, COKE, TAR, OR SIMILAR MATERIALS
- C10B21/00—Heating of coke ovens with combustible gases
- C10B21/10—Regulating and controlling the combustion
Definitions
- This invention relates to coke oven door implemented by hollow metallic door plug having bottom-less gas combustion space to provide heating function, which accelerates coking reaction of coal particles charged in the vicinity of coke oven door plug, gasifying of tar generated during coking and adhered to door and, at the same time, preventing charged coal particles enter into bottom-less combustion space of hollow metallic door plug.
- Coke battery manufactures coke by heating coal particles by the heat supplied through heating walls on both sides of coking chamber of coke oven.
- Hot coke pushed out from coke oven includes poor quality coke generated in the vicinity of both ends of coke oven because of insufficient coking.
- This poor quality coke causes low yield of good quality blast furnace coke.
- This problem arises from existing refractory door plug, which usually has about 400 mm of thickness and is heated up to a high temperature during coking operation. Heated plug is exposed to the open air when door is extracted from its service position and looses heat by radiation. When door is put in service again temperature of door plug is lower than before and it causes a delay of coking of coal particles charged in the vicinity of door plug in next coking cycle.
- Patent Document 1 discloses a "method for coking coal particles charged in the vicinity of high heat conductive metal wall of coke oven door plug by sending the generated hot coke oven gas to the gas passage through the vertical flue provided in at least one of the doors in contact with said coal charge and separated from the interior of the coke oven by the heat conductive metal wall constituting said door and moving part of said hot gas to an upper end region in contact with said partition wall therethrough by the ascending of said gas and the heat conductivity of the partition wall” and Patent Document 2 discloses a "coke oven door carrying on the inner side thereof a shield allowing passage of gases generated in the oven that comprises shielding members made up of spacers and coking plates".
- Known coke oven door structures such as those shown in Patent Document 3 and Patent Document 4 disclose coke oven door, said Coking Plate, provided gas passageway from bottom to top of its hollow plug. A part of gas generated in coking chamber flows into the hollow space and then is ignited by properly placed ignition device. Necessary air or oxygen to burn the gas is supplied from outside of the door.
- this type doors compared with those existing coke oven door using refractory plug, may have effects to increase coking speed of coal particles charged in the vicinity of coke oven door plug and decrease the generation of poor quality coke, but have not come to industrial use.
- the inventor considering above-mentioned situation, developed a coke oven door having heating function comprising air supply nozzle having air delivery-end in bottom-less combustion space of hollow metallic coke oven door plug to burn coke oven gas generated in the coking chamber and coming into said bottom-less combustion space of hollow metallic coke oven door plug as shown in Patent Document 5 and Patent Document 6.
- Air volume to be supplied is neither controlled by means of electric nor manual system but automatically determined following the behavior of gas pressure in the bottom-less combustion space of hollow metallic plug by movement of specially designed valve.
- the structure of hollow metallic coke oven door plug consists of exchangeable metallic bars and supporting brackets mounted on the coke oven side surface of insulation boxes mounted on door body.
- Patent Document 7 and Patent Document 8 (filed in Japan), also developed an air supply system equipped with a kind of check valve to protect the system itself from poor controllability caused by adhesion of viscous tar mist, small coal and/or coke particles suspended in the backward flowing coke oven gas.
- This system consists of a disk plate positioned at the top end of air intake pipe capable of moving up and down functioning as a check valve according to the gas pressure change in said bottom-less combustion space of hollow metallic door plug and additional device positioned between above-mentioned check valve and delivery end of air supply pipe for separating tar mist and small solid, coal and/or coke, particles.
- additional device is an impingement type separator set inside of air supply pipe.
- This coke oven door raises the temperature of coal particle layer in the vicinity of coke oven door plug and, at the same time, makes said solid particles and tar adhering to the foot of door plug disappear by heat generated by burning coke oven gas flowing into said bottom-less combustion space of hollow metallic door plug through the slits of metallic bars by supplying necessary amount of combustion air from outside of coking chamber. It is known, however, that the gas pressure in coking chamber fluctuates all through the coking cycle with a considerably wide range from positive to negative pressure. These phenomena may cause backward flowing of gas accompanied by said small solid particles with viscous tar mist and also clogging of air supply system in spite of above-mentioned counter measures.
- the present invention is based on the above-mentioned information.
- the outline of the invention is as follows.
- An air chamber unit having two functions is divided into two sections by labyrinth partition.
- One of said two sections contains check valve unit and the other contains separator that catches and separates mixture of tar mist and said solid particles.
- Air intake pipe is inserted into air chamber unit through bottom plate of said check valve unit section of air chamber.
- Spring supported check valve plate is set horizontally on top end of air intake pipe fitted vertically. This supporting spring has larger diameter than that of air intake pipe as to be inserted by air intake pipe.
- Air supply pipe is allocated in the opposite side section of said labyrinth partition. Air supply pipe goes down vertically through bottom plate of said separator unit section of air chamber.
- Impingement type tar mist and said solid particle separator is mounted in the tail part of air supply pipe. Tar mist and said slid particles caught by impingement flow down through vertical pipe and never stay around impingement.
- an appropriate resistance against backward gas flowing from inside of coking chamber is required.
- each labyrinth plate has an opening at its corner having appropriate gas passage area to assure complete removal of tar mist and said solid particles.
- Check valve plate moves under the delicate balance of its own weight, supporting force of coil spring and gas pressure fluctuation. Said check valve plate shall keep its horizontal posture at any moment during operation. For that purpose at least one guide piece is provided to keep said check valve plate movement correctly in vertical direction.
- a plate is provided as a stopper against excess jump-up of check valve plate.
- Another role of above-mentioned guide piece is to support this stopper plate.
- the lower end of coil spring is fixed on said air chamber bottom plate by a fitting ring.
- Another ring is fitted to lower surface of check valve plate to assure perfect contact between said check valve plate and top end of coil spring.
- Air supply pipe is connected to the line pipe that goes into above mentioned bottom-less combustion space of hollow metallic door plug.
- cylindrical cover hoods can be added to said air chamber unit.
- One having diameter larger than that of said check valve plate can be fitted above said check valve unit and the other having diameter larger than that of said air supply pipe can be fitted above tail end of said air supply pipe.
- Both hoods provide air/gas stagnant space for each section of said air chamber unit. Also impingement pieces can be fitted to inside of air supply pipe.
- the present invention provides a coke oven door equipped with a system that sends necessary amount of air to burn coke oven gas that flows through slits of metal shield bars into said hollow space of said metallic door plug under simple actions and prevents excess air supply that causes temperature drop in the bottom-less combustion space and excess oxidation of coke in front of said hollow metallic door plug. Also the present invention provides very easy maintenance control for the system. Tar mist and said solid particles suspended in backward flowing gas from bottom-less combustion space of hollow metallic door plug caused by sudden fluctuation of gas pressure do not contaminate check valve plate because those contaminants are caught by such components as impingements, labyrinth partition and stagnant spaces provided in said air chamber unit. Under this condition check valve plate operates always satisfactorily and sends necessary amount of air to the bottom-less combustion space and accelerates coking reaction of coal layer in the vicinity of metallic door plug.
- Fig.1 is a cross-sectional view in the vicinity of coke oven opening of coke delivery or pushing side illustrating an embodiment of this invention in the direction of oven height.
- reference numeral 1 designates a coke oven, 2 coal particles charged in the coke oven 1.
- combustion chambers (not shown) are located. They give heat through heating wall to coke oven 1 to produce coke.
- Reference numeral 3 is an oven door structure that opens and closes an opening 4 of coke oven 1.
- the oven door structure 3 comprises a sturdy cast iron or steel frame 5, slide plate 6 on coke oven side of frame 5, flanges with knife-edge cross section 7 that contact to door jamb 8, seal plate 9 made of heat-resistant metal plate that works as a gas sealing member in conjunction with flanges 7, inner plate 10, heat-insulation box 12 filled with insulating material 11 such as alumina silicate, isolite, ceramic fiber and other conventional insulating materials and bottom-less combustion space 13 in the metallic door plug that projects into the opening 4 of coke oven.
- insulating material 11 such as alumina silicate, isolite, ceramic fiber and other conventional insulating materials and bottom-less combustion space 13 in the metallic door plug that projects into the opening 4 of coke oven.
- Bottom-less combustion space 13 is so structured as to let coke oven gas generated from coal particles 2 charged in coke oven 4 flow easily into the bottom-less combustion space 13.
- Horizontal brackets 14 made of heat resistant steel mounted on heat-insulation box in such a manner as to partition the box into several spaces one on top of another.
- Shield bars 15 made of heat resistant steel are mounted on bracket 14 horizontally or vertically facing to the coke oven 1 and to coke oven heating walls on both sides having narrow slits or holes 16 to provide gas passage way for coke oven gas to flow into bottom-less combustion space 13 of the hollow metallic door plug structured as to be easily disassembled and reassembled.
- For horizontal shield bars two types are acceptable. One has U-shaped plan view and the other has round-cornered quadrangular plain view.
- Both types have louver type vertical cross section providing louver plate sloping from inside edge facing to said bottom-less combustion space 13 down to front edge facing to charged coal particles 2 and to said coke oven heating walls on both sides. Front edge of said shield bars are stacked up horizontally providing horizontal gas inlet slit between each bar.
- required structure for bottom-less combustion space 13 in the hollow metallic door plug is to let gas generated in coke oven 1 flow into the bottom-less combustion space 13 of hollow metallic door plug.
- structural design of hollow metallic door plug There is no limitation for structural design of hollow metallic door plug.
- Reference numeral 17 is air chamber unit for controling supply air to burn coke oven gas flowing into the bottom-less combustion space 13 of hollow metallic plug.
- Air chamber unit 17 is fitted to coke oven door 3 and the air supply pipe 44 is connected to the combustion nozzle 45 located in the bottom-less combustion space 13 of hollow metallic door plug.
- Air chamber unit 17 is a device to suck and send necessary amount of air to burn coke oven gas flowing into the bottom-less combustion space 13 of the hollow metallic door plug.
- Detail structure of air chamber 17 is as follows. Air chamber unit 17 is fitted to coke oven door 3. At least one air chamber unit shall be provided for different levels over the length of coke oven door.
- Reference numeral 18 denotes a latching device that strongly presses and fastens coke oven door 3 to the coke oven opening 4.
- Latching device 18 comprises compression springs, latching bar and fittings such as bolts and nuts and other fastening members.
- Coke oven door 3 is equipped with spring-loaded plungers 19 that freely move to and back to press flange members 7 engaged to seal-plate 9 against door jamb 8 to make tight sealing of coke oven opening 4.
- coke oven door 3 has two functions such as to open and close job of coke oven opening 4 and to burn coke oven gas that flows into the bottom-less combustion space 13 of hollow metallic door plug.
- FIG.2 and 3 shows example of air chamber unit 17 illustrated in Fig.1 by a partially omitted enlarged perspective view and an enlarged cross-sectional view of this invention.
- Reference numeral 17 is air chamber unit.
- Air chamber unit 17 is an air-tight vessel comprises bottom plate 21, top plate 22 and side wall plate 23 that makes voluntarily selected shape such as box, cylinder and others.
- Air chamber 20 is structured to suck and supply a volume of air necessary to burn coke oven gas flowing into bottom-less combustion space 13 of hollow metallic door plug.
- Air chamber unit 17 is divided into two parts, section (A) and section (B), by gas passage guide unit 24 as a partition placed in a voluntarily selected position.
- air intake pipe 27 is fitted.
- the lower end of air intake pipe 27 is the air entrance 25.
- Top end of intake pipe 27 having horizontal edge 26 is the delivery end for sucked air.
- air supply pipe 30 is fitted.
- Lower portion of air supply pipe 30 is the air delivery end 28 and upper portion is air suction end 29.
- an air supply cup 32 having at least one air intake hole 31 is provided instead of air supply pipe 30. Cup 32 is mounted in up side down position. Air supply pipe goes down through the bottom plate 21 of air chamber unit 17.
- gas passage guide unit 24 reduces the pressure and velocity of gas flowing back to air intake pipe 27 via air supply pipe 30 or air delivery cup 32 in the air chamber unit 17 to clean backward flowing gas by catching and separating tar mist and said solid particles suspended in the gas.
- Gas passage guide unit 24 comprises, the guide plate 33 having a length shorter than distance between top plate 22 and bottom plate 21 of said air chamber unit 17 fixed on the bottom plate 21 or top plate 22 of said air chamber unit 17.
- said gas passage guide unit 24 comprises at least two plates, each of said guide plate 33 providing opening at its corner as a gas flowing path 34 is fixed alternately to the top plate 22 or bottom plate 21 of air chamber unit 17.
- Guide plate 33 may have such cross section as flat, curved, waved or combination of such cross sections.
- Gas passage guide unit 24 is so formed as to let backward gas flow meanderingly into air chamber space 20 through guide plates 33.
- a check valve plate 35 is placed above the delivery end 26 of air intake pipe 27.
- Check valve plate 35 is kept in a floating position by a coil spring 36 having a diameter larger than that of air inlet pipe 27.
- a plate 37 is provided above check valve plate 35 to assure the movement of check valve plate 35 within a limited range.
- Plate 37 is mounted on top of guide piece 38 standing on the ring bracket 39 fitted on middle portion of air intake pipe 27 or on the bottom plate of air chamber unit 17.
- check valve plate 35 comes down pressing coil spring 36 down to the position to close the delivery end 26 of air intake pipe 27.
- pressure in said air chamber space 20 also becomes negative making check valve plate 35 float upward by the force of coil spring 36 and open the delivery end 26 of air intake pipe 27 to let air go into said air chamber space 20.
- ring 40 is fitted to lower surface of check valve plate 35 keeping the relative position between check valve plate 35 and the head of coil spring 36 within a preferred range.
- Ring 41 is fitted on the ring bracket 39 to keep the bottom end of coil spring 36 within a preferred position.
- Role of ring 40 and 41 is to keep check valve plate 35 in correct position always when the valve plate sits on the delivery end 26 of air intake pipe 27 during frequent vertical up and down movement of check valve plate 35.
- Rings 40 and 41 are required to keep the center of check valve plate 35 and the center of delivery end of air intake pipe 27 coincident with each other all through the operation.
- Ring 41 fixes the bottom of coil spring 36 in a selected position and does never allow any position change to the radial direction during operation.
- valve plate 35 To assure the smooth movement of check valve plate 35, it is acceptable to use such materials for said valve plate as glass, metal, plastics and mica. Among those materials, glass is superior to others because of its flatness and strength against temperature change and chemical attack. Glass is better than other materials.
- Coil spring 36 helps check valve plate 35 float when air enters into air chamber space 20 and softens the contact shock when the check valve plate 35 comes to closed position.
- Elasticity of coil spring 36 shall meet above-mentioned requirements.
- Stopper plate 37 mounted on top of check valve plate guide pieces 38 has a role to prevent excess jump-up of check valve plate 35. Possible shapes for stopper plate 37 are disk, ring, ribbon and others. At least one guide piece 38 for check valve plate shall be so positioned giving appropriate gap between guide piece surface and periphery of check valve plate 35 as not to interrupt the movement of check valve plate 35. Said guide piece 38 shall be so arranged surrounding coil spring 36 as to make air flow freely into said air chamber space 20.
- a plate 42 is fitted cylindrically to exterior of said guide piece 38.
- the upper end of plate 42 may either have a gap between stopper plate 37 or be fixed to stopper plate 37 forming a cover-hood.
- Air chamber unit 17 is connected to air supply nozzle 45 located in bottom-less combustion space 13 of the hollow metallic plug via stop valve 43 connected to the delivery end of air supply pipe 28 illustrated in Fig.3 or delivery end of air supply cup 32 illustrated in Fig.4 or air supply line 44 illustrated in Fig.1.
- stop valve 43 fitted on air delivery end of air chamber unit 17 is useful when it is necessary to stop air supply to any of individual ovens.
- the type of air delivery nozzle located in bottom-less combustion space 13 is not to be specialized. Simple pipe, multi-nozzle type and others are acceptable.
- Coke oven door having heating function presented in the present invention is operated in a same manner to that of existing coke oven doors.
- a large amount of gas is generated in coke oven 1 and delivered to dry-main (not shown) through ascension pipe (not shown) and a part of this gas flows into bottom-less combustion space 13 of hollow metallic plug and raise gas pressure in the hollow metallic door plug up to a certain positive level.
- Gas pressure in air chamber unit 17 is raised up to positive level in accordance to the gas pressure in combustion space 13.
- check valve plate 35 comes down because of the positive pressure in the air chamber unit 17 to the edge of delivery end 26 of air intake pipe 27 and isolate air chamber space 20 from open air.
- Gas pressure in coke oven becomes lower gradually along with the progress of coking reaction because of decrease of gas generation and becomes close to atmospheric pressure at around middle of coking cycle.
- gas pressure in each oven may be affected by the operation of other ovens directly because all ovens are connected by gas collecting-main (not shown). Every time when gas pressure in said bottom-less combustion space 13 of hollow metallic door plug becomes negative, gas pressure in air chamber space 20 also becomes negative. And check valve plate 35 is sucked upward and floated.
- gas pressure in air chamber space 20 also becomes positive and check valve plate 35 comes down and closes delivery end 26 of air intake pipe 27 and prevents flow-out of raw coke oven gas generated in coke oven 1 into open air.
- Raw coke oven gas flowing into air chamber space 20 through air supply pipe 30 or air delivery cup 32 fitted instead of air supply pipe 30 is cleaned by gas velocity slow down effect and labyrinth effect of partition 24.
- check valve plate 35 in the section (A) of air chamber space 20 separated by partition 24 is kept free from contamination by suspended contaminant particles in the raw coke oven gas and can continue stable supply of air necessary to burn coke oven gas that flows into bottom-less gas combustion space 13 in hollow metallic door plug for long time.
- Figs.5 and 6 illustrate other examples of air chamber unit 17 to control air supply to burn coke oven gas in bottom-less combustion space 13 of hollow metallic plug.
- Figs.5 and 6 illustrate a hood 46 having appropriate diameter installed in section (B) to provide gas stagnant space (S) above air inlet end 29 of air supply pipe 30 or air delivery cup 32 provided by at least one air inlet hole 31.
- gas stagnant space (S) in section (B) catches and removes tar mist and solids, coal and/or coke particles, suspended in the back flowing gas in front of partition 24.
- This function contributes to protect check valve plate 35 and surrounding units from contamination by such contaminants as tar mist and said solid particles, and assures stable air supply to burn coke oven gas that flows into bottom-less combustion space 13 of hollow metallic door plug and to reduce the generation of tar residual adhered around foot of coke oven door 3 effectively.
- Figs.7, 8, 9 and 10 illustrate other examples of air chamber unit 17 equipped with impingement unit 47 mounted in air supply pipe 30 or air delivery cup 32 illustrated in Figs.2 to 6.
- Impingement unit 47 reduces velocity of gas flowing backward to air chamber unit 17 through gas supply pipe 30 or air supply cup 32 in the event of sudden rise of gas pressure in said bottom-less combustion space 13 of hollow metallic door plug and catches and separates tar mist and said solid particles suspended in backward flowing gas.
- the cleaned gas remained in room (A) and (B) is sent back to said bottom-less combustion space 13 in next air supply chance.
- impingement vanes or pieces are mounted on the shaft 48 comprising impingement unit fixed, for example, directly to the top plate 22 of air chamber unit 17 or to the bottom of air delivery cup 32 placed in up side down position or by other means of supporting unit.
- Said vanes or pieces in various shapes such as flat, spiral, inclined or others are acceptable to be mounted on inner surface of air supply pipe 30 or inner surface of air delivery cup 32 also.
- Coke oven door providing heating function having bottom-less combustion space 13 provided on coking chamber side of coke oven door and air chamber unit 17 mounted on outside of coke oven door frame 5 raises temperature of coal particles charged in the vicinity of coke oven door plug by high sensible heat and combustion heat of raw coke oven gas flowing into combustion space 13 of hollow metallic plug and, as a result, reduces the generation of poor quality coke remarkably and, in other words, improves the yield of good quality blast furnace coke.
- tar adhesion to the foot of coke oven door generated under lower temperature range in early stage of coking process disappears because of heat generated by burning raw coke oven gas in the combustion space 13, and, as a result, tar-cleaning operation for coke oven door in every coke pushing operation is not required anymore.
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Abstract
An air chamber unit provided for a coke oven door enabling to suppress the generation of poor quality coke and reduce tar adhesion to coke oven door by accelerating coking reaction in the vicinity of coke oven door plug. An air chamber unit (17) is installed to control air supply to the bottom-less combustion space provided in hollow metallic coke oven door plug. For the purpose of long lasting stable air supply for said combustion space, air space (20) in the air chamber unit (17) is divided into two sections (A) and (B) by labyrinth partition to give different function for each of those section. Air intake pipe (27) is fitted in section (A) through bottom plate (21) of air chamber unit (17), wherein check valve plate (35) and other related components are provided as air supply control segments. Air supply pipe (30) or air delivery cup having one or more air inlet holes in upper portion is fitted in section (B) through bottom plate (21) of air chamber unit (17), wherein roles to remove contaminant particles suspended in backward flow gas are provided.
Description
- This invention relates to coke oven door implemented by hollow metallic door plug having bottom-less gas combustion space to provide heating function, which accelerates coking reaction of coal particles charged in the vicinity of coke oven door plug, gasifying of tar generated during coking and adhered to door and, at the same time, preventing charged coal particles enter into bottom-less combustion space of hollow metallic door plug.
- Coke battery manufactures coke by heating coal particles by the heat supplied through heating walls on both sides of coking chamber of coke oven. Hot coke pushed out from coke oven includes poor quality coke generated in the vicinity of both ends of coke oven because of insufficient coking. This poor quality coke causes low yield of good quality blast furnace coke. This problem arises from existing refractory door plug, which usually has about 400 mm of thickness and is heated up to a high temperature during coking operation. Heated plug is exposed to the open air when door is extracted from its service position and looses heat by radiation. When door is put in service again temperature of door plug is lower than before and it causes a delay of coking of coal particles charged in the vicinity of door plug in next coking cycle.
- To solve this problem, many heating type coke oven doors have been invented to accelerate temperature rise of coal layer in the vicinity of door plug by utilizing the sensible heat of high temperature gas generated in coking chamber as a heating agent. For example,
Patent Document 1 discloses a "method for coking coal particles charged in the vicinity of high heat conductive metal wall of coke oven door plug by sending the generated hot coke oven gas to the gas passage through the vertical flue provided in at least one of the doors in contact with said coal charge and separated from the interior of the coke oven by the heat conductive metal wall constituting said door and moving part of said hot gas to an upper end region in contact with said partition wall therethrough by the ascending of said gas and the heat conductivity of the partition wall" andPatent Document 2 discloses a "coke oven door carrying on the inner side thereof a shield allowing passage of gases generated in the oven that comprises shielding members made up of spacers and coking plates". - Known coke oven door structures, such as those shown in
Patent Document 3 andPatent Document 4 disclose coke oven door, said Coking Plate, provided gas passageway from bottom to top of its hollow plug. A part of gas generated in coking chamber flows into the hollow space and then is ignited by properly placed ignition device. Necessary air or oxygen to burn the gas is supplied from outside of the door. Although this type doors, compared with those existing coke oven door using refractory plug, may have effects to increase coking speed of coal particles charged in the vicinity of coke oven door plug and decrease the generation of poor quality coke, but have not come to industrial use. Possibly this is because of several reasons such as quick distortion of "coking plate" structured by steel plates caused by cyclic rapid heating-cooling during door open-close operation, scratch damage of coking chamber brick wall by distorted "coking plate" and contamination of product coke by fragments of oven wall bricks generated by distorted coking plate scratching. In addition, maintenance of ignition control system for individual door of a coke battery consists of 50 to 80 ovens is not practical under the bitter operating condition of high temperature and dusty atmosphere. Moreover, gas pressure behavior in the period later than middle of a coking cycle is too complicated and unpredictable to follow. - The inventor, considering above-mentioned situation, developed a coke oven door having heating function comprising air supply nozzle having air delivery-end in bottom-less combustion space of hollow metallic coke oven door plug to burn coke oven gas generated in the coking chamber and coming into said bottom-less combustion space of hollow metallic coke oven door plug as shown in
Patent Document 5 andPatent Document 6. Air volume to be supplied is neither controlled by means of electric nor manual system but automatically determined following the behavior of gas pressure in the bottom-less combustion space of hollow metallic plug by movement of specially designed valve. The structure of hollow metallic coke oven door plug consists of exchangeable metallic bars and supporting brackets mounted on the coke oven side surface of insulation boxes mounted on door body. Bars hang on supporting brackets mounted on said insulation boxes having certain pitches over the length of oven door giving narrow slits between each bar. Width of slit is large enough to let the gas generated in the coke oven flow into said bottom-less combustion space of hollow metallic door plug but not large as to allow charged coal particles enter into said bottom-less combustion space of hollow metallic door plug. The inventor, as shown inPatent Document 7 and Patent Document 8 (filed in Japan), also developed an air supply system equipped with a kind of check valve to protect the system itself from poor controllability caused by adhesion of viscous tar mist, small coal and/or coke particles suspended in the backward flowing coke oven gas. This system consists of a disk plate positioned at the top end of air intake pipe capable of moving up and down functioning as a check valve according to the gas pressure change in said bottom-less combustion space of hollow metallic door plug and additional device positioned between above-mentioned check valve and delivery end of air supply pipe for separating tar mist and small solid, coal and/or coke, particles. Above-mentioned additional device is an impingement type separator set inside of air supply pipe. This coke oven door raises the temperature of coal particle layer in the vicinity of coke oven door plug and, at the same time, makes said solid particles and tar adhering to the foot of door plug disappear by heat generated by burning coke oven gas flowing into said bottom-less combustion space of hollow metallic door plug through the slits of metallic bars by supplying necessary amount of combustion air from outside of coking chamber. It is known, however, that the gas pressure in coking chamber fluctuates all through the coking cycle with a considerably wide range from positive to negative pressure. These phenomena may cause backward flowing of gas accompanied by said small solid particles with viscous tar mist and also clogging of air supply system in spite of above-mentioned counter measures. -
- Patent Document 1:
JP H3-40074 B - Patent Document 2:
JP S61-49353 B - Patent Document 3:
JP 2953319 B - Patent Document 4:
JP H8-283735 A - Patent Document 5:
JP 2004-99859 A - Patent Document 6:
WO2004/007639A1 (EP1533357A1 ) - Patent Document 7:
JP 2004-276148 - Patent Document 8:
JP 2004-333740 - The inventors, after a number of various tests and trials, concluded that it is possible to continue stable coke battery operation for a long time protecting above-mentioned check valve from contamination caused by viscous tar mist and said solid particles suspended in backward flowing gas by providing labyrinth type partitions installed in the air chamber unit between above-mentioned check valve and air supply pipe equipped with impingement type separator.
- The present invention is based on the above-mentioned information. The outline of the invention is as follows. An air chamber unit having two functions is divided into two sections by labyrinth partition. One of said two sections contains check valve unit and the other contains separator that catches and separates mixture of tar mist and said solid particles. Air intake pipe is inserted into air chamber unit through bottom plate of said check valve unit section of air chamber. Spring supported check valve plate is set horizontally on top end of air intake pipe fitted vertically. This supporting spring has larger diameter than that of air intake pipe as to be inserted by air intake pipe. Air supply pipe is allocated in the opposite side section of said labyrinth partition. Air supply pipe goes down vertically through bottom plate of said separator unit section of air chamber. Impingement type tar mist and said solid particle separator is mounted in the tail part of air supply pipe. Tar mist and said slid particles caught by impingement flow down through vertical pipe and never stay around impingement. To protect check valve plate from contamination by tar mist and said solid particles completely, an appropriate resistance against backward gas flowing from inside of coking chamber is required. For this purpose each labyrinth plate has an opening at its corner having appropriate gas passage area to assure complete removal of tar mist and said solid particles. Check valve plate moves under the delicate balance of its own weight, supporting force of coil spring and gas pressure fluctuation. Said check valve plate shall keep its horizontal posture at any moment during operation. For that purpose at least one guide piece is provided to keep said check valve plate movement correctly in vertical direction. Above said check valve plate, a plate is provided as a stopper against excess jump-up of check valve plate. Another role of above-mentioned guide piece is to support this stopper plate. The lower end of coil spring is fixed on said air chamber bottom plate by a fitting ring. Another ring is fitted to lower surface of check valve plate to assure perfect contact between said check valve plate and top end of coil spring. Air supply pipe is connected to the line pipe that goes into above mentioned bottom-less combustion space of hollow metallic door plug. Thus this system composes a coke oven door that gives additional heat to charged coal particles under controlled combustion in the bottom-less combustion space of hollow metallic door plug.
- In addition to the present invention, cylindrical cover hoods can be added to said air chamber unit. One having diameter larger than that of said check valve plate can be fitted above said check valve unit and the other having diameter larger than that of said air supply pipe can be fitted above tail end of said air supply pipe. Both hoods provide air/gas stagnant space for each section of said air chamber unit. Also impingement pieces can be fitted to inside of air supply pipe.
- The present invention provides a coke oven door equipped with a system that sends necessary amount of air to burn coke oven gas that flows through slits of metal shield bars into said hollow space of said metallic door plug under simple actions and prevents excess air supply that causes temperature drop in the bottom-less combustion space and excess oxidation of coke in front of said hollow metallic door plug. Also the present invention provides very easy maintenance control for the system. Tar mist and said solid particles suspended in backward flowing gas from bottom-less combustion space of hollow metallic door plug caused by sudden fluctuation of gas pressure do not contaminate check valve plate because those contaminants are caught by such components as impingements, labyrinth partition and stagnant spaces provided in said air chamber unit. Under this condition check valve plate operates always satisfactorily and sends necessary amount of air to the bottom-less combustion space and accelerates coking reaction of coal layer in the vicinity of metallic door plug.
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- Fig.1 illustrates a cross-sectional view of a coke oven door according to this invention taken in the direction of oven height.
- Fig.2 illustrates a partially omitted, enlarged perspective view of air chamber unit. Where air intake pipe, check valve unit, labyrinth partition and the tail of air supply pipe are shown.
- Fig.3 illustrates a cross-sectional view of air chamber unit shown in Fig.2.
- Fig.4 illustrates an example of cross-sectional view where, instead of open tail-end of air supply pipe shown in Fig.3, a closed-end cup having one or more air intake holes on side wall are provided.
- Fig.5 illustrates another example of cross-sectional view where, in addition to Fig.3, a hood is fitted above the tail end of air supply pipe.
- Fig.6 illustrates another example of cross-sectional view where, in addition to Fig.4, a hood is fitted above the closed-end of air supply cup.
- Fig.7 illustrates another example of cross-sectional view where, in addition to Fig.3, impingement pieces are added in the air supply pipe.
- Fig.8 illustrates another example of cross-sectional view where, in addition to Fig.4, impingement pieces are added in the air supply cup.
- Fig.9 illustrates another example of cross-sectional view where, in addition to Fig.5, impingement pieces are added in the air supply pipe.
- Fig.10 illustrates another example of cross-sectional view where, in addition to Fig.6, impingement pieces are added in the air supply cup.
- Details of this invention will be described by reference to the drawings. Fig.1 is a cross-sectional view in the vicinity of coke oven opening of coke delivery or pushing side illustrating an embodiment of this invention in the direction of oven height. In Fig.1
reference numeral 1 designates a coke oven, 2 coal particles charged in thecoke oven 1. On both sides ofcoke oven 1 combustion chambers (not shown) are located. They give heat through heating wall tocoke oven 1 to produce coke. -
Reference numeral 3 is an oven door structure that opens and closes anopening 4 ofcoke oven 1. Theoven door structure 3 comprises a sturdy cast iron orsteel frame 5,slide plate 6 on coke oven side offrame 5, flanges with knife-edge cross section 7 that contact todoor jamb 8,seal plate 9 made of heat-resistant metal plate that works as a gas sealing member in conjunction withflanges 7,inner plate 10, heat-insulation box 12 filled with insulating material 11 such as alumina silicate, isolite, ceramic fiber and other conventional insulating materials and bottom-less combustion space 13 in the metallic door plug that projects into theopening 4 of coke oven. - Bottom-less combustion space 13 is so structured as to let coke oven gas generated from
coal particles 2 charged incoke oven 4 flow easily into the bottom-less combustion space 13. Horizontal brackets 14 made of heat resistant steel mounted on heat-insulation box in such a manner as to partition the box into several spaces one on top of another. Shield bars 15 made of heat resistant steel are mounted on bracket 14 horizontally or vertically facing to thecoke oven 1 and to coke oven heating walls on both sides having narrow slits orholes 16 to provide gas passage way for coke oven gas to flow into bottom-less combustion space 13 of the hollow metallic door plug structured as to be easily disassembled and reassembled. For horizontal shield bars, two types are acceptable. One has U-shaped plan view and the other has round-cornered quadrangular plain view. Both types have louver type vertical cross section providing louver plate sloping from inside edge facing to said bottom-less combustion space 13 down to front edge facing to chargedcoal particles 2 and to said coke oven heating walls on both sides.
Front edge of said shield bars are stacked up horizontally providing horizontal gas inlet slit between each bar. In this invention, required structure for bottom-less combustion space 13 in the hollow metallic door plug is to let gas generated incoke oven 1 flow into the bottom-less combustion space 13 of hollow metallic door plug. There is no limitation for structural design of hollow metallic door plug. -
Reference numeral 17 is air chamber unit for controling supply air to burn coke oven gas flowing into the bottom-less combustion space 13 of hollow metallic plug.Air chamber unit 17 is fitted tocoke oven door 3 and the air supply pipe 44 is connected to the combustion nozzle 45 located in the bottom-less combustion space 13 of hollow metallic door plug.Air chamber unit 17 is a device to suck and send necessary amount of air to burn coke oven gas flowing into the bottom-less combustion space 13 of the hollow metallic door plug. Detail structure ofair chamber 17 is as follows.Air chamber unit 17 is fitted tocoke oven door 3. At least one air chamber unit shall be provided for different levels over the length of coke oven door. Reference numeral 18 denotes a latching device that strongly presses and fastenscoke oven door 3 to thecoke oven opening 4. Latching device 18 comprises compression springs, latching bar and fittings such as bolts and nuts and other fastening members.Coke oven door 3 is equipped with spring-loadedplungers 19 that freely move to and back topress flange members 7 engaged to seal-plate 9 againstdoor jamb 8 to make tight sealing ofcoke oven opening 4. In this inventioncoke oven door 3 has two functions such as to open and close job ofcoke oven opening 4 and to burn coke oven gas that flows into the bottom-less combustion space 13 of hollow metallic door plug. - Each of Figs.2 and 3 shows example of
air chamber unit 17 illustrated in Fig.1 by a partially omitted enlarged perspective view and an enlarged cross-sectional view of this invention.Reference numeral 17 is air chamber unit.Air chamber unit 17 is an air-tight vessel comprises bottom plate 21,top plate 22 and side wall plate 23 that makes voluntarily selected shape such as box, cylinder and others.Air chamber 20 is structured to suck and supply a volume of air necessary to burn coke oven gas flowing into bottom-less combustion space 13 of hollow metallic door plug. -
Air chamber unit 17 is divided into two parts, section (A) and section (B), by gaspassage guide unit 24 as a partition placed in a voluntarily selected position. In section (A)air intake pipe 27 is fitted. The lower end ofair intake pipe 27 is the air entrance 25. Top end ofintake pipe 27 havinghorizontal edge 26 is the delivery end for sucked air. In section (B)air supply pipe 30 is fitted. Lower portion ofair supply pipe 30 is the air delivery end 28 and upper portion isair suction end 29. In Fig.4 anair supply cup 32 having at least oneair intake hole 31 is provided instead ofair supply pipe 30.Cup 32 is mounted in up side down position. Air supply pipe goes down through the bottom plate 21 ofair chamber unit 17. - When gas pressure in the bottom-less combustion space 13 in hollow metallic plug is positive, gas
passage guide unit 24 reduces the pressure and velocity of gas flowing back toair intake pipe 27 viaair supply pipe 30 orair delivery cup 32 in theair chamber unit 17 to clean backward flowing gas by catching and separating tar mist and said solid particles suspended in the gas. Gaspassage guide unit 24 comprises, the guide plate 33 having a length shorter than distance betweentop plate 22 and bottom plate 21 of saidair chamber unit 17 fixed on the bottom plate 21 ortop plate 22 of saidair chamber unit 17. When said gaspassage guide unit 24 comprises at least two plates, each of said guide plate 33 providing opening at its corner as a gas flowing path 34 is fixed alternately to thetop plate 22 or bottom plate 21 ofair chamber unit 17. Guide plate 33 may have such cross section as flat, curved, waved or combination of such cross sections. Gaspassage guide unit 24 is so formed as to let backward gas flow meanderingly intoair chamber space 20 through guide plates 33. - In order to control the flow rate of air being supplied to bottom-less combustion space 13 of hollow metallic door plug, a
check valve plate 35 is placed above thedelivery end 26 ofair intake pipe 27. Checkvalve plate 35 is kept in a floating position by a coil spring 36 having a diameter larger than that ofair inlet pipe 27. Abovecheck valve plate 35, aplate 37 is provided to assure the movement ofcheck valve plate 35 within a limited range.Plate 37 is mounted on top of guide piece 38 standing on thering bracket 39 fitted on middle portion ofair intake pipe 27 or on the bottom plate ofair chamber unit 17. Thus inside pressure ofair chamber space 20 of this invention becomes positive when the gas pressure in bottom-less combustion space 13 becomes positive because of flow-in of coke oven gas into hollow metallic door plug. In the event of positive pressure inair chamber space 20,check valve plate 35 comes down pressing coil spring 36 down to the position to close thedelivery end 26 ofair intake pipe 27. On the other hand, when gas pressure in said bottom-less combustion space 13 becomes negative, pressure in saidair chamber space 20 also becomes negative makingcheck valve plate 35 float upward by the force of coil spring 36 and open thedelivery end 26 ofair intake pipe 27 to let air go into saidair chamber space 20. - In the present invention, ring 40 is fitted to lower surface of
check valve plate 35 keeping the relative position betweencheck valve plate 35 and the head of coil spring 36 within a preferred range. Ring 41 is fitted on thering bracket 39 to keep the bottom end of coil spring 36 within a preferred position.
Role of ring 40 and 41 is to keepcheck valve plate 35 in correct position always when the valve plate sits on thedelivery end 26 ofair intake pipe 27 during frequent vertical up and down movement ofcheck valve plate 35. Rings 40 and 41 are required to keep the center ofcheck valve plate 35 and the center of delivery end ofair intake pipe 27 coincident with each other all through the operation. Ring 41 fixes the bottom of coil spring 36 in a selected position and does never allow any position change to the radial direction during operation. - To assure the smooth movement of
check valve plate 35, it is acceptable to use such materials for said valve plate as glass, metal, plastics and mica. Among those materials, glass is superior to others because of its flatness and strength against temperature change and chemical attack. Glass is better than other materials. - Coil spring 36 helps
check valve plate 35 float when air enters intoair chamber space 20 and softens the contact shock when thecheck valve plate 35 comes to closed position. Elasticity of coil spring 36 shall meet above-mentioned requirements. -
Stopper plate 37 mounted on top of check valve plate guide pieces 38 has a role to prevent excess jump-up ofcheck valve plate 35. Possible shapes forstopper plate 37 are disk, ring, ribbon and others. At least one guide piece 38 for check valve plate shall be so positioned giving appropriate gap between guide piece surface and periphery ofcheck valve plate 35 as not to interrupt the movement ofcheck valve plate 35. Said guide piece 38 shall be so arranged surrounding coil spring 36 as to make air flow freely into saidair chamber space 20. - To rectify the flow of air delivered from the
end 26 ofair intake pipe 27, a plate 42 is fitted cylindrically to exterior of said guide piece 38. The upper end of plate 42 may either have a gap betweenstopper plate 37 or be fixed tostopper plate 37 forming a cover-hood. -
Air chamber unit 17 is connected to air supply nozzle 45 located in bottom-less combustion space 13 of the hollow metallic plug via stop valve 43 connected to the delivery end of air supply pipe 28 illustrated in Fig.3 or delivery end ofair supply cup 32 illustrated in Fig.4 or air supply line 44 illustrated in Fig.1. In the present invention, when clogging or damage happens inair chamber unit 17 or connected pipe line, it is convenient to make maintenance work, disassembling or parts exchanging, easy by adapting screw joint fabrication method. Stop valve 43 fitted on air delivery end ofair chamber unit 17 is useful when it is necessary to stop air supply to any of individual ovens. The type of air delivery nozzle located in bottom-less combustion space 13 is not to be specialized. Simple pipe, multi-nozzle type and others are acceptable. - Coke oven door having heating function presented in the present invention is operated in a same manner to that of existing coke oven doors. In earlier stage of coking of
coal particles 2, a large amount of gas is generated incoke oven 1 and delivered to dry-main (not shown) through ascension pipe (not shown) and a part of this gas flows into bottom-less combustion space 13 of hollow metallic plug and raise gas pressure in the hollow metallic door plug up to a certain positive level. Gas pressure inair chamber unit 17 is raised up to positive level in accordance to the gas pressure in combustion space 13. During this period,check valve plate 35 comes down because of the positive pressure in theair chamber unit 17 to the edge ofdelivery end 26 ofair intake pipe 27 and isolateair chamber space 20 from open air. Gas pressure in coke oven becomes lower gradually along with the progress of coking reaction because of decrease of gas generation and becomes close to atmospheric pressure at around middle of coking cycle. However, a considerable wide ranged and frequent fluctuation of gas pressure between positive and negative within a very short time continues during all period of coking cycle therethrough. The reason of this fluctuation is not clear at the moment. The inventor estimates that the gas pressure in each oven may be affected by the operation of other ovens directly because all ovens are connected by gas collecting-main (not shown). Every time when gas pressure in said bottom-less combustion space 13 of hollow metallic door plug becomes negative, gas pressure inair chamber space 20 also becomes negative. Andcheck valve plate 35 is sucked upward and floated. A volume of air flows intoair chamber space 20 corresponding to the time whencheck valve plate 35 is kept floating and burns coke oven gas in said bottom-less combustion space 13 of hollow metallic door plug. When gas pressure in bottom-less combustion space 13 of hollow metallic door plug becomes positive, gas pressure inair chamber space 20 also becomes positive andcheck valve plate 35 comes down and closesdelivery end 26 ofair intake pipe 27 and prevents flow-out of raw coke oven gas generated incoke oven 1 into open air. Raw coke oven gas flowing intoair chamber space 20 throughair supply pipe 30 orair delivery cup 32 fitted instead ofair supply pipe 30 is cleaned by gas velocity slow down effect and labyrinth effect ofpartition 24. A part of removed mist and particles suspended in the raw coke oven gas that flows into theair chamber space 20 falls down inair delivery cup 32 or on the bottom plate of section (B) ofair chamber space 20. Accordingly checkvalve plate 35 in the section (A) ofair chamber space 20 separated bypartition 24 is kept free from contamination by suspended contaminant particles in the raw coke oven gas and can continue stable supply of air necessary to burn coke oven gas that flows into bottom-less gas combustion space 13 in hollow metallic door plug for long time. - Figs.5 and 6 illustrate other examples of
air chamber unit 17 to control air supply to burn coke oven gas in bottom-less combustion space 13 of hollow metallic plug. Figs.5 and 6 illustrate a hood 46 having appropriate diameter installed in section (B) to provide gas stagnant space (S) aboveair inlet end 29 ofair supply pipe 30 orair delivery cup 32 provided by at least oneair inlet hole 31. In the event of sudden rise of gas pressure in bottom-less combustion space 13 in hollow metallic door plug, high velocity flowing back of raw coke oven gas toair chamber unit 17 may occur. Gas stagnant space (S) in section (B) catches and removes tar mist and solids, coal and/or coke particles, suspended in the back flowing gas in front ofpartition 24. This function contributes to protectcheck valve plate 35 and surrounding units from contamination by such contaminants as tar mist and said solid particles, and assures stable air supply to burn coke oven gas that flows into bottom-less combustion space 13 of hollow metallic door plug and to reduce the generation of tar residual adhered around foot ofcoke oven door 3 effectively. - Figs.7, 8, 9 and 10 illustrate other examples of
air chamber unit 17 equipped withimpingement unit 47 mounted inair supply pipe 30 orair delivery cup 32 illustrated in Figs.2 to 6.Impingement unit 47 reduces velocity of gas flowing backward toair chamber unit 17 throughgas supply pipe 30 orair supply cup 32 in the event of sudden rise of gas pressure in said bottom-less combustion space 13 of hollow metallic door plug and catches and separates tar mist and said solid particles suspended in backward flowing gas. The cleaned gas remained in room (A) and (B) is sent back to said bottom-less combustion space 13 in next air supply chance. Although the shape and structure of impingement vanes or pieces are not specified, as illustrated in Figs.7, 8, 9 and 10, for example, spiral shaped vanes are mounted on theshaft 48 comprising impingement unit fixed, for example, directly to thetop plate 22 ofair chamber unit 17 or to the bottom ofair delivery cup 32 placed in up side down position or by other means of supporting unit. Said vanes or pieces in various shapes such as flat, spiral, inclined or others are acceptable to be mounted on inner surface ofair supply pipe 30 or inner surface ofair delivery cup 32 also. In conclusion, backward flowing raw coke oven gas fromcoke oven 1 through bottom-less combustion space 13 to theair chamber unit 17 impinges on impingement vanes or pieces existing inair supply pipe 30 orair delivery cup 32 while going through those flow route and decreases its velocity and loses a large part of such suspended contaminants as tar mist and said solid particles. Remaining suspended contaminants are removed when the gas goes throughlabyrinth partition unit 24. Accordingly, theair space 20 of room (A) andcheck valve plate 35 in theair chamber unit 17 are protected bylabyrinth partition unit 24 from contamination by tar mist and said solid particles suspended in backward flowing raw coke oven gas assuring long lasting stable supply of air necessary to burn coke oven gas flowing into bottom-less combustion space 13 of hollow metallic door plug. - In the present invention, comparison Fig.3, for example, with Figs.7 and 8, makes it obvious that said coke oven operation does not change even when there are partial differences in the inside structure of
air chamber unit 17.Labyrinth partition 24 andimpingement unit 47 remove suspended tar mist and said solid particles in the backward flowing gas and assure long lasting stable air supply to burn raw coke oven gas flowing into bottom-less combustion space 13 of hollow metallic plug suppressing tar generation and adhesion around the foot of coke oven door. - Coke oven door providing heating function having bottom-less combustion space 13 provided on coking chamber side of coke oven door and
air chamber unit 17 mounted on outside of cokeoven door frame 5 raises temperature of coal particles charged in the vicinity of coke oven door plug by high sensible heat and combustion heat of raw coke oven gas flowing into combustion space 13 of hollow metallic plug and, as a result, reduces the generation of poor quality coke remarkably and, in other words, improves the yield of good quality blast furnace coke. In addition, tar adhesion to the foot of coke oven door generated under lower temperature range in early stage of coking process disappears because of heat generated by burning raw coke oven gas in the combustion space 13, and, as a result, tar-cleaning operation for coke oven door in every coke pushing operation is not required anymore. Heat supply from door plug side raises the mechanical strength of coke produced in the vicinity of door plug and reduces coke cake collapsing during pushing operation and minimizes the damage of coke oven heating wall. By applying the present invention to the existing coke batteries, their lives are prolonged. The practical application of the present invention for existing coke batteries has already started in Japan. It is predicted that application of the present invention for both existing and newly constructed batteries will increase in the near future as an effective measure for not only economical but also environmental purposes.
Claims (6)
- An air chamber unit being connected to bottom-less combustion space provided in hollow metallic door plug of a coke oven door comprising: an air space divided into two sections 1 and 2 by a plurality of labyrinth partition plates working as gas passage guide; said section 1 equipped with air intake pipe having horizontal top edge inserted into said section 1 through bottom plate of said air chamber unit; said section 2 equipped with air supply pipe or air supply cup having at least one air inlet hole laterally in upper part of said air supply pipe or air supply cup being inserted through said bottom plate of said air chamber unit; top end of said air supply pipe or at least one air inlet hole of said air supply cup to work as air inlet; lower end of said air supply pipe or said air supply cup to work as air exit; exit end of said air supply pipe or air supply cup connecting to air supply line supplying air to said bottom-less combustion space provided in said hollow metallic door plug; a removable check valve plate mounted on top of said air intake pipe delivery end; a suspension coil spring fitted surrounding said air intake pipe to keep said check valve plate in floating position; at least one guide piece arranged outside of said suspension coil spring assuring correct up and down movement of said check valve plate; a stopper plate supported and placed above said check valve plate by said guide piece to prevent excess jump-up of said check valve plate; a cylinder-shaped air and/or gas flow guide plate fitted to exterior of upper part of said guide pieces keeping gap between said guide piece and said guide plate; a ring fitted to the lower surface of said check valve plate to keep appropriate relative position between said check valve plate and said coil spring head within a preferred range; and another ring fixed on a said ring-bracket fitted to said air intake pipe body or to said bottom plate of said air chamber unit keeping the bottom end of said suspension coil spring within a preferred position.
- An air chamber unit connected to bottom-less combustion space provided in hollow metallic door plug of a coke oven door comprising: an air space divided into two sections 1 and 2 by a plurality of labyrinth partition plates working as gas passage guide; said section 1 equipped with air intake pipe with horizontal top edge inserted into said section 1 through bottom plate of said air chamber unit; said section 2 equipped with air supply pipe or air delivery cup having at least one air inlet hole laterally in its upper part of said air supply pipe or air delivery cup being inserted through said bottom plate of said air chamber unit; top end of said air supply pipe or at least one air inlet hole of said air delivery cup to work as air inlet; lower end of said air supply pipe or said air delivery cup to work as air exit; exit end of said air supply pipe or air delivery cup connecting to air supply line supplying air to said bottom-less combustion space provided in said hollow metallic door plug; a hood with a diameter larger than that of said air supply pipe or said air supply cup with its bottom up position installed in said section 2 to provide a gas stagnant space; a removable check valve plate mounted on top of said air intake pipe delivery end; a suspension coil spring fitted surrounding said air intake pipe keeping said check valve plate in floating position; one or more guide pieces arranged outside of said suspension coil spring assuring correct up and down movement of said check valve plate; a stopper plate supported and placed above said check valve plate by said guide pieces to prevent excess jump-up of said check valve plate; a cylinder shaped air and/or gas flow guide plate fitted to exterior of upper part of said guide pieces keeping gap between said guide pieces and said guide plate; a ring fitted to the lower surface of said check valve plate keeping appropriate relative position between said check valve plate and said coil spring head within a preferred range; and another ring fixed on a said ring-bracket fitted to said air intake pipe body or to said bottom plate of said air chamber unit keeping the bottom end of said suspension coil spring within a preferred position.
- An air chamber unit being connected to bottom-less combustion space provided in hollow metallic door plug of a coke oven door comprising: an air space divided into two sections 1 and 2 by a plurality of labyrinth partition plates working as gas passage guide; said section 1 equipped with air intake pipe having horizontal top edge inserted into said section 1 through bottom plate of said air chamber unit; said section 2 equipped with air supply pipe or air delivery cup having at least one air inlet hole in upper portion of said air supply pipe or air delivery cup being inserted through said bottom plate of said air chamber unit; impingement vanes or pieces inserted inside of said air supply pipe or air delivery cup; said section 2 equipped with said air supply pipe or said air delivery cup; exit end of said air supply pipe or said air delivery cup connecting to air supply line sending air to said bottom-less combustion space of said hollow metallic door plug; a removable check valve plate mounted on top of said air intake pipe delivery end; a suspension coil spring being fitted surrounding said air intake pipe keeping said check valve plate in floating position; at least one guide piece arranged outside of said suspension coil spring assuring correct up and down movement of said check valve plate; a stopper plate supported and placed above said check valve plate by said guide piece to prevent excess jump-up of said check valve plate; a cylinder-shaped air and/or gas flow guide plate being fitted to exterior of upper part of said guide piece keeping gap between said guide piece and said guide plate; a ring fitted to the lower surface of said check valve plate keeping appropriate relative position between said check valve plate and said coil spring head within a preferred range; and another ring fixed on a said ring-bracket being fitted to said air intake pipe body or to said bottom plate of said air chamber unit to keep the bottom end of said suspension coil spring within a preferred position.
- An air chamber unit being connected to bottom-less combustion space provided in hollow metallic door plug of a coke oven door comprising: an air space divided into two sections 1 and 2 by a plurality of labyrinth partition plates which work as gas passage guide; said section 1 equipped with air intake pipe with horizontal top edge inserted into said section 1 through bottom plate of said air chamber unit; said section 2 equipped with air supply pipe or air delivery cup having at least one air inlet hole laterally in upper portion of said air supply pipe or air derivery cup being inserted through bottom plate of said air chamber unit; a hood having a diameter larger than that of said air supply pipe or said air delivery cup being fitted to above said air supply pipe or said air delivery cup to provide a gas stagnant space in said section 2; a removable check valve plate mounted on top of said air intake pipe delivery end; a suspension coil spring fitted to surrounding said air intake pipe to keep said check valve plate in floating position; at least one guide piece arranged outside of said suspension coil spring assuring correct up and down movement of said check valve plate; a stopper plate supported and placed above said check valve plate by said guide pieces to prevent excess jump-up of said check valve plate; a cylinder shaped air and/or gas flow guide plate fitted to exterior of upper part of said guide pieces keeping gap between said guide pieces and said guide plate; a ring fitted to the lower surface of said check valve plate to keep appropriate relative position between said check valve plate and said coil spring head within a preferred range; and another ring fixed on a said ring-bracket fitted to said air intake pipe body or to said bottom plate of said air chamber unit to keep the bottom end of said suspension coil spring within a preferred position.
- An air chamber unit of a coke oven door according to claims 1 to 4, further including; more than two plates shorter than the distance between top and bottom plate of said air chamber unit; top or bottom edge of each of said plates fixed to top or bottom plate of said air chamber unit; said plates provided additional gas passage opening on their left or right corners; and labyrinth unit structured by said plates as labyrinth elements.
- An air chamber unit of a coke oven door according to claims 3 and 4, further including impingement vanes or pieces mounted on suspension shaft being fixed to top plate of air chamber unit or top of air delivery cup.
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
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JP2005084745A JP4714493B2 (en) | 2005-02-22 | 2005-02-22 | Heating furnace lid for coke carbonization furnace |
JP2005122919A JP4729334B2 (en) | 2005-03-24 | 2005-03-24 | Coke carbonization furnace lid for promoting temperature rise of coal particles charged in the furnace lid |
PCT/JP2006/302949 WO2006090663A1 (en) | 2005-02-22 | 2006-02-20 | Temperature raising furnace door for coke carbonization furnace |
Publications (1)
Publication Number | Publication Date |
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EP1854866A1 true EP1854866A1 (en) | 2007-11-14 |
Family
ID=36927303
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
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EP06714090A Withdrawn EP1854866A1 (en) | 2005-02-22 | 2006-02-20 | Temperature raising furnace door for coke carbonization furnace |
Country Status (4)
Country | Link |
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US (1) | US20080271985A1 (en) |
EP (1) | EP1854866A1 (en) |
KR (1) | KR20070107096A (en) |
WO (1) | WO2006090663A1 (en) |
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- 2006-02-20 EP EP06714090A patent/EP1854866A1/en not_active Withdrawn
- 2006-02-20 WO PCT/JP2006/302949 patent/WO2006090663A1/en active Application Filing
- 2006-02-20 KR KR1020077019986A patent/KR20070107096A/en not_active Application Discontinuation
- 2006-02-20 US US11/884,810 patent/US20080271985A1/en not_active Abandoned
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
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CN104870614A (en) * | 2012-12-28 | 2015-08-26 | 太阳焦炭科技和发展有限责任公司 | Systems and methods for controlling air distribution in a coke oven |
Also Published As
Publication number | Publication date |
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KR20070107096A (en) | 2007-11-06 |
WO2006090663A1 (en) | 2006-08-31 |
US20080271985A1 (en) | 2008-11-06 |
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