KR101025799B1 - Dust collecting apparatus at kiln entrance of coke oven - Google Patents

Abstract

PURPOSE: A dust collecting device at entrance of coke oven is provided to absorb dirty gas discharged from oven entrance by changing the dirty gas flow direction to the inside of a nozzle part. CONSTITUTION: A dust collecting device at entrance of coke oven comprises a dust collecting hood and an intake port. The dust collecting hood surrounds the outside of the oven entrance. The nozzle part(31) having an inlet(311) is located at a leading end part(313a). The nozzle part is installed inside the dust collecting hood. The intake port is located on the upper side of nozzle part and side part of the oven entrance.

Description

Kiln entrance dust collector of coke furnace {DUST COLLECTING APPARATUS AT KILN ENTRANCE OF COKE OVEN}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a kiln inlet dust collector for collecting coke oven for collecting dust-containing gas discharged from a kiln inlet of a carbonization chamber of coke oven.

BACKGROUND ART Conventionally, a kiln inlet dust collector for a coke oven having a dust collecting hood disposed outside and surrounding the kiln inlet as a coke oven dust collecting apparatus and a duct connected to the dust collecting hood is known (for example, a patent). Documents 1 and 2). According to such a kiln inlet dust collecting device, a dust collecting gas discharged from the kiln inlet in the carbonization chamber is collected by a dust collecting hood, and the dust collecting gas collected by the dust collecting hood is sucked into the duct, thereby removing the dust containing gas in a dust removing apparatus. Can send impregnated gas.

Japanese Utility Model Publication No. 51-120354 Japanese Utility Model Publication No. 59-40424

By the way, in the kiln inlet dust collecting apparatus which concerns on patent documents 1 and 2, since the front-end | tip of a duct is connected to the cover of the upper part or side part of a dust collection hood, the suction inlet for inhaling a dust containing gas is arrange | positioned in the cover of the dust collection hood. . Therefore, since the intake port is separated from the inlet port, the impregnated gas discharged from the inlet port may not be efficiently sucked from the inlet port.

Therefore, in view of such a situation, an object of this invention is to provide the kiln inlet dust collector which can efficiently suck | fill the impregnated gas discharged from the kiln inlet.

The kiln inlet dust collector of the coke oven according to the present invention includes a dust collection hood disposed outside and surrounding the kiln inlet to collect dust-containing gas emitted from the kiln inlet of the carbonization chamber of the coke oven, and the dust collection hood. In a kiln inlet collecting device for a coke oven having a duct for sucking dust contained therein, the duct includes a nozzle portion having a suction port for sucking the contained gas, and the nozzle portion includes an inside of the dust collecting hood. The suction port is disposed on the side surface of the nozzle inlet side and the upper surface of the nozzle unit, respectively.

According to the kiln inlet dust collector of the coke oven according to the present invention, a nozzle portion having a suction port for sucking the gas contained therein is formed at the tip end of the duct. And since the nozzle part is arrange | positioned inside the dust collection hood, the suction inlet is arrange | positioned in the vicinity of a kiln inlet, As a result, the impregnated gas discharge | released from the kiln inlet can be sucked efficiently.

And since the intake port is arranged on the side of the nozzle inlet side, at least a part of the impregnated gas discharged from the inlet port can be sucked directly from the inlet port (before being collected by the dust collection hood). In addition, when the impregnated gas which is lighter than the atmosphere is collected by the dust collection hood, the impregnated gas stays above the nozzle portion, but since the suction port is also disposed on the upper surface of the nozzle portion, the dust contained in the dust collected by the dust collection hood is sucked in from the suction port. It can be done.

Moreover, in the kiln inlet dust collector of the coke oven which concerns on this invention, in order to guide | induce the gas to a suction port, a nozzle part may be provided with the suction guide plate arrange | positioned so that it may protrude from a suction port.

According to the kiln inlet dust collector of such a coke oven having such a structure, the suction part is provided with the suction guide plate arrange | positioned so that it may protrude from a suction port. As a result, when the impregnated gas discharged from the kiln inlet and flows upwards passes near the suction guide plate, the "coanda effect" changes the flow direction of the impregnated gas to follow the suction guide plate. I can guide you. In addition, a "coanda effect" means the property of a viscous fluid whose flow direction changes along the object when the object is placed in the flow.

Moreover, in the kiln kiln inlet dust collecting apparatus which concerns on this invention, the suction guide plate may be formed so that it may be curved from the front-end | tip part to the base end part.

According to the kiln inlet dust collector of the coke oven which has such a structure, the suction guide plate is formed so that it may be curved from the front-end | tip part to the base end part. Thereby, in the coanda effect, when the flow direction of the impregnated gas passing near the suction guide plate is changed to follow the suction guide plate, the flow of the impregnated gas can be smoothly changed. Therefore, it is possible to smooth the flow of the impregnated gas in the vicinity of the suction guide plate.

Moreover, in the kiln inlet dust collecting apparatus which concerns on this invention, the suction port arrange | positioned at the side of the kiln inlet side of a nozzle part is arrange | positioned above the said side surface, and the suction guide plate is arrange | positioned so that it may protrude from the said suction port. The distal end portion may be disposed downward from the distal end toward the proximal end.

According to the kiln inlet dust collector of the coke oven which has such a structure, the suction guide plate protrudes from the suction port arrange | positioned at the side of the kiln inlet side of a nozzle part. And since the suction guide plate is arrange | positioned so that it may face downward from a front-end | tip part toward a base end part, the flow direction of the impregnated gas which passes through the vicinity of a suction guide plate will change to a downward direction by a Coanda effect.

Therefore, since the impregnated gas passes in the downward direction, the impregnated gas which changed the flow direction can flow reliably inside the nozzle part through the suction port arrange | positioned above the side of the side of the kiln inlet side of a nozzle part. That is, the impregnated gas whose flow direction has changed can be suppressed from flowing out of the nozzle part.

As described above, according to the kiln inlet dust collector of the coke oven according to the present invention, it exhibits an excellent effect that it is possible to efficiently suck up the dust contained in the kiln inlet.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 shows an overall schematic elevation view of a coke production facility equipped with a kiln inlet dust collecting device according to an embodiment of the present invention.
2 shows a principal part schematic plan view of a coke production plant according to the embodiment.
3 shows a perspective view of a main part of a kiln entrance dust collecting device according to the embodiment.
FIG. 4 is a sectional view of a main portion of the kiln inlet dust collecting device according to the embodiment, which is taken along the line AA of FIG. 3.
Fig. 5 shows a plan view of the main part of the kiln entrance dust collecting device according to the embodiment.
FIG. 6: is a principal part view of the duct of the kiln entrance dust collecting apparatus which concerns on this embodiment, FIG. 6 (a) shows the side view seen from the kiln entrance side, FIG. 6 (b) shows the top view, and FIG. 6 (c) ) Shows the side view seen from the direction orthogonal to FIG. 6 (a).
FIG. 7: is a principal part view of the duct of the kiln entrance dust collecting apparatus which concerns on the same embodiment, and liquid duct, and shows a partially cutaway perspective view. FIG.
FIG. 8: is a principal part view of the duct of the kiln entrance dust collecting apparatus which concerns on the same embodiment, and a liquid rod duct, and shows a longitudinal cross-sectional view.
FIG. 9: is a longitudinal cross-sectional view of the principal part of the duct of the kiln entrance dust collecting apparatus which concerns on the same embodiment. FIG. 9 (a) shows the explanatory drawing of operation | movement when a suction guide plate does not exist, FIG. 9 (b) shows a suction guide plate Explanatory drawing of operation | movement when there exists is shown.
Fig. 10 is a cross sectional view of a main part of a duct of a kiln inlet dust collecting apparatus according to the embodiment, in which Fig. 10 (a) shows an operation explanatory diagram when no suction guide plate exists, and Fig. 10 (b) shows a suction guide plate. The operation explanatory drawing in the case of doing is shown.

EMBODIMENT OF THE INVENTION Hereinafter, one Embodiment in the kiln inlet dust collecting apparatus for coke oven which concerns on this invention is described referring FIG. 1-10.

A kiln inlet dust collector (hereinafter, also simply referred to as a "kiln inlet dust collector") according to the present embodiment is provided in a coke production facility. Here, before demonstrating each structure of the kiln entrance dust collecting apparatus 1, a coke manufacturing facility is demonstrated.

As shown in FIG. 1 and FIG. 2, the coke production plant is provided with a plurality of carbonization chambers 811,... Which are used to dry-dry raw material coal (hereinafter also referred to as "parallel direction"). ). And the coke manufacturing equipment is equipped with the charging car which inject | pours coal into the carbonization chamber 811 from the upper part of the carbonization chamber 811.

In addition, the coke manufacturing equipment includes a coke extruder 83 for extruding coke dried in one kiln inlet 811a of the carbonization chamber 811 into the extrusion ram 83, and the extruded coke to the other kiln inlet 811a. And a cock guide car 84 for guiding the guide device 841 therefrom. Moreover, the coke manufacturing equipment is provided with the bucket trolley 85 which receives the coke guided by the coke guide vehicle 84 as the bucket 851. As shown in FIG.

The coke oven 81 is arranged along the juxtaposition direction so as to cover the top of the furnace lids 812,..., And the kiln inlet 811a for sealing the kiln inlets 811a of the carbonization chamber 811 and to cover the upper side thereof. The long coating part 813 is provided. The plurality of carbonization chambers 811,... Are each formed in a long shape, and are arranged side by side in the width direction (horizontal direction orthogonal to the length direction).

The coke extruder 83 is equipped with the extruder main body 833 which travels on the track | orbit 832 along a juxtaposition direction, in order to be movable in a juxtaposition direction (henceforth a "movement direction"). In addition, the coke guide vehicle 84 also includes a guide vehicle body 843 that travels on the rail 842 along the juxtaposition direction in order to be movable in the juxtaposition direction similarly to the coke extruder 83.

And the coke extruder 83 is the leveler 834 which equalizes the coal level in each carbonization chamber 811, the furnace cover demounting apparatus 835 which attaches and detaches the furnace cover 812, and the furnace cover 812 which isolate | separated. ), A furnace lid cleaning apparatus 836 is provided. In addition, the leveler 834 is inserted into the carbonization chamber 811 from a small lid opening (not shown and not shown) formed in the upper portion of the furnace lid 812.

Moreover, in the coke extruder 83, when the cover (covering and not shown) which covers the small cover opening is opened (when averaging work etc.) in order to level | coal the coal level with the leveler 834. And the carbonization chamber 811 when the furnace lid 812 is separated by the furnace lid attachment and detachment device 835 (such as during the extrusion operation) in order to push the coke into the extrusion ram 831. The impregnated gas is discharged from the kiln inlet 811a. Moreover, in the coke extruder 83, even when the furnace cover cleaning apparatus 836 cleans the furnace cover 12 from which it isolate | separated, impregnated gas (air mixed with dust) generate | occur | produces from the position near the kiln inlet 811a. .

As shown in FIGS. 1-8, the kiln inlet dust collector 1 which concerns on this embodiment contains the dust-containing gas Y discharge | released from the kiln inlet 811a of the carbonization chamber 811 of the coke oven 81 at least. And a duct 3 for sucking in the dust-collecting gas Y collected by the dust-collecting hood 2 to the inside. Moreover, the kiln inlet dust collecting apparatus 1 is a vibration suppression process which damp-proofs the liquid rod duct 4 connected to the duct 3, and the impregnated gas Y conveyed via the duct 3 and the liquid rod duct 4. Apparatus 5 is provided.

The dust collection hood 2 is provided with the upper cover 21 arrange | positioned so that the outer side and the upper side of the kiln inlet 811a may be covered, and the side cover 22 arrange | positioned so that the outer side and the side of the kiln inlet 811a may be covered. . In addition, the dust collecting hood 2 is provided with movable pieces 23, 23, 23 which can be contacted / removed with the covering portion 813 of the coke oven 81, and operating means for operating the respective movable pieces 23 (this embodiment). In the form, a cylinder) (24, ...) is provided.

And the dust collection hood 2 is being fixed to the extruder main body 833, and is comprised so that the outer side of the kiln inlet 811a and surrounding the predetermined space above may be carried out. In addition, in the dust collection hood 2 and the duct 3, the direction orthogonal to the parallel direction (namely, the longitudinal direction of the carbonization chamber 811) is called "front-back direction", and is close to the kiln inlet 811a. The direction to lose is "front" and the direction away from the kiln inlet 811a is called "rear."

The upper cover 21 is set to the magnitude | size which can prevent leakage of the impregnated gas Y generate | occur | produced in the kiln inlet 811a and its vicinity. Specifically, the upper cover 21 is disposed so as to cover the tip end of the extrusion ram 831, the tip end of the leveler 834, the furnace lid detaching apparatus 835, and the furnace lid cleaning apparatus 836 from above. .

The side cover 22 extends downward from the rear side ends of the side parts 221 and 221 arrange | positioned so that it may hang down from each edge part in the parallel direction of the upper cover 21, and the upper cover 21. As shown in FIG. And a rear portion 222 which is disposed to throw. In addition, the height (dimension of the up-down direction) of each side part 211 is set so that it may become higher than the height (dimension of the up-down direction) of the rear part 222. As shown in FIG.

Each movable piece 23 is connected to the front end of the upper cover 21, and the actuation means 24 expands and contracts, thereby rotating the juxtaposition direction about the center (B arrow direction in FIG. 4). And each movable piece 23 is in contact with the cover part 813 of the coke oven 81 in order to cover the clearance gap between the dust collection hood 2 and the coke oven 81 (of the solid line in FIG. 4). Position) and a separation position spaced apart from the coating portion 813 of the coke oven 81 to prevent the coke extruder 83 from interfering with the coating portion 813 of the coke oven 81 when it moves. Position of the dividing line).

The duct 3 has a plurality (in this embodiment, three) having suction ports 311 and 321 and 331 for suctioning the impregnated gas Y at the tip end of the upstream side (the kiln inlet 811a side). Nozzle portions 31, 32, 33. And the duct 3 is the duct main body 34 extended from the nozzle part 31,32,33 toward the liquid sealing duct 4, and the connection part arrange | positioned in the downstream front end part, and connected to the liquid sealing duct 4 ( 35).

Each nozzle part 31, 32, 33 is arrange | positioned inside the dust collection hood 2. As shown in FIG. Specifically, each nozzle part 31, 32, 33 is the outer side of the kiln inlet 811a of the coke oven 81, and is arrange | positioned inside the side cover 22 of the dust collection hood 2, It is arranged above the kiln inlet 811a of the coke oven 81 and below the upper cover 21 of the dust collection hood 2.

More specifically, the 1st nozzle part 31 is arrange | positioned above the leveler 834 in order to suck in the impregnated gas Y discharge | released from the kiln inlet 811a when a small cover is opened, and the 2nd nozzle part The 32 is disposed above the furnace lid cleaning apparatus 836 in order to suck in the impregnated gas Y generated when the furnace lid cleaning apparatus 836 cleans the furnace lid 12. The furnace lid 812 is disposed above the extrusion ram 831 to suck in the impregnated gas Y discharged from the separated kiln inlet 811a.

 The 1st nozzle part 31 is equipped with the nozzle body 312 of the hollow shape (box shape) in which the suction port 311 is formed. Moreover, the 1st nozzle part 31 has a plurality of suction guide plates 313 and 313 arrange | positioned so that it may protrude toward the outward from the suction port 311 in order to guide the impregnated gas Y to the suction port 311 (this embodiment In the form, two pieces) are provided. In addition, the 1st nozzle part 31 is provided with the airflow guide board 314 of several (4 in this embodiment) arrange | positioned inside, in order that the impregnated gas Y suctioned from the suction port 311 may flow uniformly. ).

The suction port 311 is provided with the side opening (front opening) 311a arrange | positioned at the side surface (front surface) 312a by the side of the kiln inlet 811a of the nozzle main body 312, and the upper surface 312b of the nozzle main body 312. The upper surface sphere 311b arrange | positioned at is provided. And the side surface sphere 311a is arrange | positioned above the side surface (front surface) 312a of the nozzle main body 312, and the upper surface sphere 311b is the front side of the upper surface 312b of the nozzle main body 312. (Front end side). And the side surface sphere 311a and the upper surface sphere 311b are formed in series (it is formed integrally).

Each suction guide plate 313 is formed in a long plate shape along the juxtaposition direction. And each suction guide plate 313 is arrange | positioned so that it may protrude from the side surface sphere 311a, and it will be directed toward the base end part 313b from the front-end | tip part 313a (specifically, the suction port 311 from the kiln inlet 811a side). Facing down). Each suction guide plate 313 is formed to be curved from the distal end portion 313a to the proximal end portion 313b. In addition, the plurality of suction guide plates 313 and 313 are arranged in parallel in the vertical direction and parallel to each other.

Each airflow guide plate 314 is formed in a long plate shape along the vertical direction. And each airflow guide plate 314 is arrange | positioned in the vicinity of the upper surface opening 311b, and is directed from the suction port 311 toward the center of the rectangular parallelepiped nozzle main body 312 (or the center of the duct main body 34). It is formed to be curved. The plurality of airflow guide plates 314 are arranged in parallel in the horizontal direction (horizontal direction) and in parallel with each other.

The duct main body 34 has a first front end duct part 341 connected to the first nozzle part 31 and the second nozzle part 32, and an upstream end thereof to the third nozzle part 33. It is provided with the 2nd front end duct part 342 connected. Moreover, the duct main body 34 is provided with the joining duct part 343 which joins the 1st and 2nd front end duct parts 341 and 342 on the downstream side.

Further, the duct body 34 extends downward from the downstream end of the horizontal portion 344 along the horizontal duct portion 344 extending backward from the confluence portion 343 along the horizontal direction and along the vertical direction. It is provided with a vertical duct section 345. And the duct main body 34 is connected with the connection part 35 in the lower end part of the vertical duct part 345. In addition, the duct main body 34 is fixed to the extruder main body 833.

The joining duct part 343 is provided with the switching valve 343a for changing the area which communicates with the 1st front end duct part 341, and the area which communicates with the 2nd front end duct part 342. As shown in FIG. And the joining duct part 343 flows from each front end duct part 341 and 342 by rotating the switching valve 343a formed in plate shape about the up-down direction to the center (C arrow direction in FIG. 5). The flow rate of the impregnated gas Y, that is, the flow rate of the gas sucked from each suction port 311, 321, 331 is changed.

Specifically, the switching valve 343a includes a first position (position of the double-dotted line in FIG. 5) for mainly flowing downstream the impregnated gas Y from the first end duct portion 341, and the second position. 2nd position (position of the dashed-dotted line in FIG. 5) for flowing the impregnated gas Y from the front end duct part 342 mainly downstream, and the impregnated gas Y from both front end duct parts 341 and 342. ) Can be switched to the third position (position of the broken line in FIG. 5) for flowing downstream.

The vertical duct portion 345 is disposed along the up-down direction, and is formed such that the downstream side thereof is elongated along the moving direction (the D arrow direction in FIG. 7). Specifically, the vertical duct portion 345 is formed such that the upstream side is formed in a substantially rectangular shape, and the downstream side is formed in a long direction along the moving direction, and is gradually extended in the moving direction from the upstream side to the downstream side. .

The connection part 35 is provided inside in order to send the impregnated gas Y conveyed from the dust collection hood 2 via the duct main body 34 toward the damping apparatus 5 (in the direction of the E and F arrows of FIG. 8). It is provided with the cylindrical connection part main body 351 to flow. And the connection part 35 is equipped with the flow path parts 352 and 352 extended in a cylindrical shape along a moving direction in order to distribute the liquid X inside. Moreover, each flow path part 352 is arrange | positioned so that it may protrude from the connection part main body 351 in the direction orthogonal to a moving direction.

Moreover, the connection part 35 protrudes from the connection part main body 351 in the direction orthogonal to a movement direction, and lowers the protrusion parts 353 and 353 which extend along a movement direction than the flow path part 352. It is provided in the side. Moreover, the connection part 35 is extended so that the liquid X in the liquid rod duct 4 may pass, and is arrange | positioned so that the lower side may be immersed in the liquid X in the liquid rod duct 4.

Each flow path part 352 presses the liquid X (liquid surface X1) in the liquid rod duct 4 which rises as the connection part 35 (coke extruder 83) moves, from an upper part. Moreover, each flow path part 352 has an inner side (between the connection part main body 351) and the outer side (between the liquid sealing duct 4) by the side part as the connection part 35 (coke extruder 83) moves. The liquid (X) is separated into the liquid.

The liquid rod duct 4 is a liquid tank 41 disposed along the moving direction and filled with the liquid X therein, and a gas tank disposed along the liquid tank 41 (moving direction) and blocked from the outside. I) 42 and a gas communicating part 43 for communicating the liquid tank 41 and the base 42 with each other. And even if the duct 3 (connection part 35) moves, the connection state of the duct part 3 which moves to the ground, and the liquid rod duct 4 fixed to the ground is maintained continuously.

The liquid tank 41 is arranged along the direction of movement and is open to the upper side 411, and the rear tank disposed along the precursor 411 and cut off from the outside of the liquid rod duct 4 (412) and a liquid communication portion (413) for communicating the lower side of the front tank (411) and the lower side of the rear tank (412). And the liquid tank 41 fills the back tank 412 (specifically, the gas which fills the upper side of the back tank 412) by the liquid communication part 413 being filled with liquid X (sealed with water). It cuts off from the outside of the duct 4. In other words, the liquid tank 41 is filled with the liquid X on the lower side and filled with gas on the upper side.

The base 42 has a connection port 421 connected to the connection pipe 52 of the vibration suppression apparatus 5 on the upper side in order to send the gas Y contained in the vibration suppression apparatus 5. Moreover, the base 42 is communicating with the upper side of the rear tank 412 of the liquid tank 41 through the gas communicating part 43. Specifically, the gas communicating part 43 communicates the upper side of the base 42 with the upper side of the rear bath 412. That is, the base 42 and the gas communication part 43 are filled with the whole gas.

The vibration damping apparatus 5 is a suction means for suctioning the impregnated gas Y via the duct 3 and the liquid sealing duct 4, in order to suck the gas Y contained in the suction ports 311, 321, 331. (For example, a blower) 51 and the processing means 53 which are connected to the liquid sealing duct 4 via the connection pipe 52, and process the impregnated gas Y sucked by the suction means 51, Equipped. Moreover, the vibration damping apparatus 5 is being fixed to the ground.

The structure of the kiln inlet dust collector 1 of the coke oven which concerns on this embodiment is as having been strange, Next, operation | movement of the kiln inlet dust collector 1 of the coke oven which concerns on this embodiment is demonstrated.

First, the function of the suction guide plates 313 and 313 will be described with reference to FIG. 9. First, as shown in FIG. 9 (a), when the suction guide plate 313 does not exist, the position of the vicinity of the suction port 311 is determined among the impregnated gases Y1 and Y2 discharged from the kiln inlet 811a and raised. Flowing impregnated gas Y1 is sucked into the inside of the 1st nozzle part 31 through the suction port 311 by receiving the force attracted from the suction port 311.

However, although the impregnated gas Y2 which flows in the position away from the inlet port 311 changes a flow direction by the force suctioned from the inlet port 311, it is not sucked into the inside of the 1st nozzle part 31, and is dust-collecting hood. It is collected once in (2). Therefore, only the impregnated gas Y1 flowing near the suction port 311 is directly sucked into the inside of the first nozzle part 31.

On the other hand, as shown in FIG.9 (b), when the suction guide plates 313 and 313 exist, it contains the impregnated gas Y1 which flows in the vicinity of the suction port 311, and flows in the position away from the suction port 311. FIG. The impregnated gas Y2 passes near the suction guide plates 313 and 313 protruding from the suction port 311. Then, the impregnated gases Y1 and Y2 receive not only the force sucked from the suction port 311 but also the coanda effect of each suction guide plate 313, so that the flow direction changes to follow each suction guide plate 313.

Thereby, the impregnated gas Y1 which flows in the vicinity of the inlet port 311 and the impregnated gas Y2 which flows in the position away from the inlet port 311 pass through the inlet port 311, and the inside of the 1st nozzle part 31 is carried out. Aspirated by Therefore, not only the impregnated gas Y1 which flows in the vicinity of the suction port 311 but also the impregnated gas Y2 which flows in the position away from the suction port 311 is directly sucked in the inside of the 1st nozzle part 31. FIG. .

Next, the function of the airflow guide plates 314,... Will be described with reference to FIG. 10. First, as shown in FIG. 10A, when the airflow guide plate 314 does not exist, the impregnated gases Y3 to Y5 sucked from the suction port 311 are formed in the first tip duct portion 341. The coanda effect of the side walls 341a and 341b is affected. Accordingly, the impregnated gases Y3 to Y5 are concentrated on both sides near the side walls 341a and 341b when the flow direction is changed by about 90 degrees from the first nozzle portion 31 to the first tip duct portion 341. It does not flow much in the center.

On the other hand, as shown in FIG.10 (b), when there exists an airflow guide plate 314, ..., the impregnated gas which flows in the position away from the airflow guide plate 314, ... among the impregnated gas sucked in from the suction port 311. FIG. (Y3, Y4) receives the coanda effect of the side walls 341a and 341b in the first tip duct portion 341. Therefore, these impregnated gases Y3 and Y4 flow in both sides of the vicinity of the side walls 341a and 341b.

However, among the impregnated gases sucked from the suction port 311, the impregnated gas Y5 which flows in the vicinity of the airflow guide plates 314, ... receives the Coanda effect of each airflow guide plate 314, so that the flow direction is angular. It is changed to follow the airflow guide plate 314. Thereby, the impregnated gas Y5 which flows in the vicinity of the airflow guide plate 314, ... flows through the center in the 1st front end duct part 341. As shown in FIG.

Accordingly, the impregnated gases Y3 to Y5 are used within the first tip duct part 341 when the flow direction is changed by about 90 degrees from the first nozzle part 31 to the first tip duct part 341. This flows to make the flow distribution uniform. Therefore, it is possible to prevent the flow of the impregnated gases Y3 to Y5 from stagnation, and to smoothly flow the impregnated gases Y3 to Y5 toward the downstream side.

As mentioned above, according to the kiln inlet dust collector 1 which concerns on this embodiment, the nozzle part which has the suction ports 311, 321, 331 for inhaling the impregnated gas Y in the front-end | tip part of the duct 3, (31, 32, 33) are formed. And since the nozzle parts 31, 32, 33 are arrange | positioned inside the dust collection hood 2, the suction inlets 311, 321, 331 are arrange | positioned in the vicinity of the kiln inlet 811a, As a result, a kiln The impregnated gas Y discharged from the inlet 811a and its vicinity can be sucked.

Moreover, according to the kiln inlet dust collecting apparatus 1 which concerns on this embodiment, the side surface (front surface) 311a of the suction port 31 is arrange | positioned at the side surface (front surface) 312a of the nozzle part 31. It is. Thereby, a part of the dust-containing gas Y discharged from the kiln inlet 811a is directly, that is, from the side opening (front opening) 311a of the suction opening 311 before being collected by the dust collection hood 2. May be inhaled.

By the way, when the dust-containing gas Y is collected by the dust collection hood 2, it will stay above the nozzle part 31. FIG. However, since the upper surface port 311b of the inlet port 311 is also arranged on the upper surface 312b of the nozzle part 31, the dust-containing gas Y collected by the dust collection hood 2 is used for the inlet port 311. Inhalation can be made from the upper surface sphere 311b. Therefore, the impregnated gas Y discharged from the kiln inlet 811a can be sucked efficiently by the suction port 311.

Moreover, according to the kiln inlet dust collector 1 of the coke oven concerning this embodiment, the suction guide plates 313 and 313 arrange | positioned so that it may protrude from the suction port 311 are formed. Thus, when the impregnated gas Y discharged from the kiln inlet 811a flows upward, passes through the vicinity of the suction guide plates 313 and 313, the flow direction of the impregnated gas Y is changed by the suction guide plate by the coanda effect. Since it changes so that it may follow 313, the impregnated gas Y can be guided toward the suction port 311. FIG.

Moreover, according to the kiln inlet dust collecting apparatus 1 which concerns on this embodiment, each suction guide plate 313 is formed to bend from the front-end | tip part 313a to the base end 313b. Thereby, with a coanda effect, when the flow direction of the impregnated gas Y which passes in the vicinity of the suction guide plate 313 changes so that it may follow the suction guide plate 313, the flow of the impregnated gas Y can be changed gently. . Therefore, the flow of the impregnated gas Y in the vicinity of each suction guide plate 313 can be made smooth.

Moreover, according to the kiln inlet dust collecting apparatus 1 which concerns on this embodiment, each suction guide plate 313 protrudes from the side surface 311a of the suction port 311 of the nozzle part 31. As shown in FIG. And since each suction guide plate 313 is arrange | positioned downward toward the base end part 313b from the front-end | tip part 313a, the oscillation gas Y which passes through the vicinity of each suction guide plate 313 by a Coanda effect. ) Flow direction changes downward.

Therefore, since the impregnated gas Y passes through the side opening (front opening) 311a of the suction opening 311 arrange | positioned above the side surface (front surface) 312a of the nozzle part 31 in the downward direction. The impregnated gas Y whose flow direction is changed can be reliably flown inside the nozzle part 31. That is, the impregnated gas Y whose flow direction changed can be suppressed from flowing out of the nozzle part 31.

Moreover, according to the kiln inlet dust collecting apparatus 1 which concerns on this embodiment, the airflow guide plate 314, ... is formed in the inside of the nozzle part 31. As shown in FIG. Thereby, when the impregnated gas Y which flows inside the nozzle part 31 passes near the airflow guide plates 314, ..., the flow direction of the impregnated gas Y will become the airflow guide plate 314 by the coanda effect. Since it changes so as to follow, the flow distribution of the impregnated gas Y in the inside of the nozzle part 31 and the inside of the duct main body 34 can be made uniform, and as a result, the flow of the impregnated gas Y I can do it smoothly.

Moreover, according to the kiln inlet dust collecting apparatus 1 which concerns on this embodiment, each flow path part 352 is extended in the cylinder shape so that the axial center direction (length direction) may follow a moving direction. As a result, as the duct 3 moves, even if the liquid X flows into each of the flow path portions 352, since the flow path portion 352 is blocked in a cylindrical shape, The liquid X can be prevented from escaping, and as a result, the liquid X (liquid surface X1) in the liquid rod duct 4 can be suppressed from rising.

In addition, as the duct 3 moves, the liquid X flows into and out of each of the flow path portions 352. Here, since the Taylor vortex (vortex which arises between a moving object and a fixed object) generate | occur | produces outside each flow path part 352, such a Taylor vortex becomes a resistance, and it is inside the each flow path part 352. It is possible to promote the flow of the liquid X, and as a result, the rise of the liquid X (the liquid surface X1) in the liquid rod duct 4 outside the flow path portion 352 can be suppressed.

In addition, the kiln inlet dust collecting apparatus which concerns on this invention is not limited to said embodiment, Of course, various changes can be added within the range which does not deviate from the summary of this invention. Moreover, of course, you may select a structure, a method, etc. which concern on the various modified examples mentioned below, and employ | adopt for the structure, the method which concern on said embodiment, etc., of course.

For example, in the kiln inlet dust collecting apparatus according to the present invention, the second nozzle portion 32 and / or the third nozzle portion 33 adopt a configuration substantially the same as the first nozzle portion 31. You may also

Moreover, in the kiln inlet dust collecting apparatus 1 which concerns on the said embodiment, the case where the side opening 311a and the upper surface opening 311b of the suction opening 311 were formed integrally was demonstrated, In this case, It is not limited. For example, the side surface sphere 311a and the upper surface sphere 311b may be formed separately from each other.

Moreover, although the case where two suction guide plates 313 and 313 were formed in the kiln kiln inlet dust collector 1 which concerns on the said embodiment was demonstrated, it is not limited to this case. For example, the suction guide plate 313 is not an essential structure, and the quantity is not limited, either. Accordingly, the suction guide plate 313 may not be formed, or may be formed when one is provided, or may be formed when three or more suction guide plates 313 are formed.

Moreover, in the kiln inlet dust collector 1 of the coke oven which concerns on the said embodiment, the case where the suction guide plate 313 is arrange | positioned so that it may protrude from the side opening 311a of the suction port 311 was demonstrated, but it is limited to such a case. It doesn't work. For example, the suction guide plate 313 may be disposed so as to protrude from the upper surface port 311b of the suction port 311.

In addition, in the coke oven dust collecting apparatus 1 of the coke oven which concerns on the said embodiment, the case where the suction guide plate 313 was formed to be curved from the front-end | tip part 313a to the base-end | tip part 313b was demonstrated, but it is limited to such a case. It doesn't work. For example, the suction guide plate 313 may be formed in a linear shape from the tip portion 313a to the proximal end portion 313b, and may also be a portion and a linear shape curved at the proximal end portion 313b from the distal end portion 313a. It may be the case of providing the site | part of.

Moreover, in the kiln inlet dust collector 1 of the coke oven which concerns on the said embodiment, the case where the suction guide plate 313 was arrange | positioned toward the base end part 313b from the front end part 313a was demonstrated, but it was such a case. It is not limited to the case. For example, the suction guide plate 313 may be disposed so as to face upward from the distal end portion 313a toward the distal end portion 313b, and is disposed so as to be horizontal across the distal end portion 313b from the distal end portion 313a. It may be the case.

In addition, in the kiln inlet dust collector 1 of the coke oven according to the embodiment described above, the kiln inlet dust collector 1 is discharged and generated from the kiln inlet 811a on the side of the coke extruder 83 and generated therein. Although the case where (Y) was collected was described, it is not limited to such a case. For example, the kiln inlet dust collecting apparatus 1 may collect the dust-containing gas Y discharged | emitted and generate | occur | produced in the kiln inlet 811a of the side of the cock guide vehicle 84, and its vicinity.

One… Kiln entrance dust collector, 2... Dust collection hood, 3... Duct, 31... Nozzle part 311... Inlet, 312a... Side, 312b... Top surface, 313... Suction guide plate, 313a... Tip, 313b... Proximal end 81... Coke oven, 811... Carbonization chamber, 811a... Kiln entrance, Y… Impregnated gas

Claims (4)

In order to collect the impregnated gas discharged from the kiln inlet of the carbonization chamber of coke oven, the dust collection hood which is arrange | positioned outward and encloses the upper part of the kiln inlet, and the duct which inhales the impregnated gas collected by the dust collection hood inside are provided. In kiln entrance collecting device to coke to say,
The duct is provided with a nozzle portion having a suction port for suctioning the impregnated gas at the tip end thereof,
The nozzle part is disposed inside the dust collecting hood,
The suction port is disposed on the side surface of the nozzle inlet side and the upper surface of the nozzle unit, respectively, the kiln inlet dust collector of the coke oven, characterized in that. The method of claim 1,
The nozzle part is a kiln inlet dust collector of the coke oven provided with a suction guide plate which is arranged to protrude from the suction port in order to guide the contained gas to the suction port. The method of claim 2,
The suction guide plate is a kiln inlet dust collecting device which is formed to be bent from the distal end to the proximal end. The method according to claim 2 or 3,
The suction port arranged in the side surface of the nozzle inlet side of a nozzle part is arrange | positioned above the said side surface,
The suction guide plate is arranged to protrude from the suction port, and is a kiln inlet dust collecting device arranged to be directed downward from the distal end toward the proximal end.

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