KR101046554B1 - Duct connecting structure for dust collecting apparatus at kiln entrance of coke oven and moving duct - Google Patents

Abstract

PURPOSE: A duct connecting structure for a dust collecting device at kiln entrance to cokes and movable duct are provided to prevent liquid in a liquid sealing duct from excessively rising or falling as a movable duct moves. CONSTITUTION: A movable duct(3) moves in a given direction. A liquid sealing duct(2) is arranged in a direction, in which the movable duct moves. The liquid is charged in the liquid sealing duct. The movable duct is arranged in the liquid sealing duct and thus a connecting unit(32) connected to the liquid sealing duct is arranged on the front end. The lower part of the connecting unit is immersed in the liquid. The connecting unit comprises a liquid pressing unit(322a) protruded in a direction orthogonal to a moving direction to press the liquid rising as the movable duct moves.

Description

Duct connection structure and moving duct for kiln entrance dust collector of coke furnace {DUCT CONNECTING STRUCTURE FOR DUST COLLECTING APPARATUS AT KILN ENTRANCE OF COKE OVEN AND MOVING DUCT}

The present invention relates to a duct connection structure for a kiln inlet dust collector of a coke oven provided with a moving duct moving along a predetermined direction and a liquid rod duct connected to the moving duct. Moreover, this invention relates to the moving duct which equips the front end side with the connection part connected to a liquid rod duct by arrange | positioning in the liquid rod duct arrange | positioned along a predetermined direction.

Conventionally, as a coke oven mover with respect to a coke oven (ground), the coke extruder which extrudes the coke of a carbonization chamber, the coke guide car which introduces extruded coke to a bucket trolley, a coke guide car, and dry fire extinguishing BACKGROUND ART Hood cars and the like that move in synchronization with bucket carts are known. And the impregnated gas which generate | occur | produced and collected by the coke oven mover is conveyed to a damping apparatus through a connection structure, and is processed by the damping apparatus.

Moreover, as a connection structure which connects a coke oven moving apparatus and a damping apparatus, as shown in FIG. 7, the liquid rod duct 92 in which the liquid X is filled inside, and the connection part 932 connected to the liquid rod duct 92 are shown. The duct connection structure provided with the moving duct 93 which has a front end side is known (for example, patent document 1). The moving duct 93 is fixed to the coke oven mover, and the liquid rod duct 92 is connected to the vibration suppression apparatus.

Thereby, the impregnated gas Y which generate | occur | produced in the coke oven mover and collected is not leaked to the outside, and can convey the impregnated gas to a damping apparatus. Moreover, in general, the liquid sealing duct 92 is designed to be compact in order to reduce the cost (initial cost or running cost) or to reduce the installation space.

Japan Utility Model Publication No. 50-7583

Here, in the duct connection structure which concerns on patent document 1, the moving duct 93 is formed in substantially U shape, and the lower side of the connection part 932 is immersed in the liquid X in the liquid sealing duct 92. to be. Therefore, as the moving duct 93 moves, the liquid X (liquid level X1) in the liquid rod duct 92 rises or falls accordingly.

For this reason, when the liquid X rises too much, the liquid X will flow out of the liquid rod duct 92, or the liquid X will be conveyed to the downstream equipment (vibration damper etc.) with the impregnated gas Y. There is a case. Moreover, when liquid X falls too much, since the sealing property of the liquid sealing duct 92 falls, the impregnated gas Y may not be conveyed to a damping apparatus.

Therefore, in view of such a situation, an object of this invention is to provide the duct connection structure for the kiln inlet dust collector for coke oven which prevents the liquid in a liquid rod duct to rise or fall too much as a moving duct moves. Another object of the present invention is to provide a moving duct which prevents the liquid in the liquid rod duct from excessively rising or falling as it moves.

The duct connection structure for the kiln inlet dust collector for coke oven which concerns on this invention is provided with the moving duct which moves along a predetermined direction, and the liquid rod duct which is arrange | positioned along the moving direction which a moving duct moves, and a liquid is filled inside. In the duct connection structure in which the moving duct is disposed in the liquid rod duct and connected to the liquid rod duct at the distal end side, and the connecting portion is disposed so that the lower side is immersed in the liquid, the connecting portion is raised as the moving duct moves. In order to press liquid, it is provided with the liquid press part arrange | positioned above and protruding in the direction orthogonal to a movement direction.

According to the duct connection structure for the coke oven dust collecting apparatus which concerns on this invention, a moving duct moves in a moving direction in the state in which the lower side of the connection part arrange | positioned in a liquid sealing duct is immersed in the liquid in a liquid sealing duct. And the liquid press part is arrange | positioned above the connection part and protrudes in the direction orthogonal to a movement direction. Thereby, when the liquid (liquid surface) in a liquid rod duct rises as a moving duct moves, the liquid which rises to a liquid press part can be pressed.

Moreover, in the duct connection structure for the coke oven dust collecting apparatus which concerns on this invention, a connection part protrudes toward a downward side from a liquid press part, in order to flow a liquid inward and outward as a moving duct moves. Moreover, you may be provided with the sorting part arrange | positioned along a movement direction.

According to the duct connection structure for the coke oven dust collecting apparatus of such a structure, a water flow part protrudes downward from a liquid press part, and is arrange | positioned along a movement direction. As a result, the liquid flows into the inside and outside of the fractionation section as the moving duct moves. Here, since the Taylor vortex (vortex occurring between the moving object and the fixed object) is generated outside of the fractionation section, this Taylor vortex becomes a resistance to promote the flow of liquid into the fractionation section, and as a result, It can suppress that the liquid (liquid surface) in a liquid rod duct rises from the outer side of a part.

Moreover, in the duct connection structure for the coke oven dust collecting apparatus which concerns on this invention, a connection part is provided with the flow path part extended in a cylindrical shape along a movement direction, in order to distribute a liquid inside, and a flow path part protrudes in the direction orthogonal to a movement direction. It is arrange | positioned so that a liquid press part may comprise the upper part of a flow path part, and a dividing part may comprise the side part of a flow path part.

According to the duct connection structure for the coke oven dust collector of such a structure, the flow path part which protrudes in the direction orthogonal to a moving direction extends in a cylindrical shape along the moving direction. Thereby, even if liquid flows into the flow path part as the moving duct moves, the flow path part is blocked in a cylindrical shape, and thus liquid is prevented from escaping from the inside of the flow path part.

In addition, since the dividing portion constitutes the side portion of the flow path portion, the liquid can be promoted to flow into the flow passage portion, and even if a large amount of liquid flows into the flow passage portion, the liquid pressing portion constitutes the upper portion of the flow passage portion, so that the liquid is pressed. It is possible to reliably press the liquid rising to the negative.

Moreover, the moving duct which concerns on this invention is arrange | positioned along the predetermined direction, and is arrange | positioned in the liquid rod duct in which a liquid is filled, and is provided in the front end side with the connection part connected to a liquid rod duct, When moving to the said predetermined direction, In the movement duct arrange | positioned so that the lower side may be immersed in liquid, a connection part is a liquid press part arrange | positioned on an upper side and protrudes in the direction orthogonal to the said predetermined direction, in order to press | move the liquid which rises as it moves to the said predetermined direction. It is characterized by including.

According to the moving duct which concerns on this invention, a moving duct moves in the state in which the lower side of the connection part arrange | positioned in a liquid sealing duct is immersed in the liquid in a liquid sealing duct. And the liquid press part is arrange | positioned above the connection part, and protrudes in the direction orthogonal to the direction (direction to which a moving duct moves) in which a liquid rod duct is arrange | positioned. Thereby, when the liquid (liquid surface) in a liquid rod duct rises as a moving duct moves, the liquid which rises to a liquid press part can be pressed.

Moreover, in the moving duct which concerns on this invention, in order to classify a liquid inward and outward as it moves to the said predetermined direction, the classification part protrudes downward from a liquid press part and is arrange | positioned along the said predetermined direction. You may be provided.

According to the moving duct of such a structure, the dividing part protrudes toward the downward side from a liquid press part, and is arrange | positioned along the direction in which the liquid rod duct is arrange | positioned (the direction to which a moving duct moves). As a result, the liquid flows into the inside and outside of the fractionation section as the moving duct moves. And since the Taylor vortex which generate | occur | produces on the outer side of a dividing part becomes a resistance, it can promote the flow of a liquid inside the dividing part, and as a result, it can suppress that the liquid (liquid surface) in a liquid bar duct rises from the outer side of a dividing part.

Moreover, in the moving duct which concerns on this invention, a connection part is provided with the flow path part extended in a cylindrical shape along the said predetermined direction, in order to distribute a liquid inside, and the flow path part is arrange | positioned so that it may protrude in the direction orthogonal to the said predetermined direction, The pressing portion may constitute an upper portion of the flow passage portion, and the dividing portion may constitute a side portion of the flow passage portion.

According to the moving duct of such a structure, the flow path part which protrudes in the direction orthogonal to the direction in which the liquid rod duct is arrange | positioned (the direction to which the moving duct moves) is a cylindrical shape along the direction in which the liquid rod duct is arrange | positioned (the direction in which the moving duct moves). Extends. Thereby, even if liquid flows into the flow path part as the moving duct moves, the flow path part is blocked in a cylindrical shape, and thus liquid is prevented from escaping from the inside of the flow path part.

In addition, since the dividing portion constitutes the side portion of the flow path portion, the liquid can be promoted to flow into the flow passage portion, and even if a large amount of liquid flows into the flow passage portion, the liquid pressing portion constitutes the upper portion of the flow passage portion, so that the liquid is pressed. It is possible to reliably press the liquid rising to the negative.

As mentioned above, according to the duct connection structure for the kiln inlet dust collector of the coke oven concerning this invention, the outstanding effect is prevented that the liquid in a liquid rod duct rises or falls too much as a moving duct moves. Moreover, according to the moving duct which concerns on this invention, the outstanding effect of preventing the liquid in a liquid rod duct to rise or fall too much as it moves is shown.

BRIEF DESCRIPTION OF THE DRAWINGS The whole schematic of the coke manufacturing equipment provided with the duct connection structure which concerns on one Embodiment of this invention is shown.
2 is a schematic view of a main part of the duct connection structure according to the embodiment, showing a partially cutaway perspective view.
3 is a schematic view of a main part of the duct connection structure according to the embodiment, showing a longitudinal cross-sectional view.
FIG. 4 is a schematic view of the main part of the moving duct according to the embodiment, showing a sectional view taken along line BB of FIG. 3.
FIG. 5 is a schematic view of principal parts explaining the operation of the duct connection structure according to the embodiment, wherein (a) and (b) each show a cross-sectional view taken along line BB of FIG. 3.
6 is a schematic view of a main part of a duct connection structure according to another embodiment of the present invention, wherein (a) and (b) each shows a longitudinal cross-sectional view.
7 is a schematic view of a main part of a conventional duct connection structure, showing a longitudinal cross-sectional view.

EMBODIMENT OF THE INVENTION Hereinafter, one Embodiment in the duct connection structure for the kiln inlet dust collector for coke oven which concerns on this invention, and a moving duct is demonstrated in reference to FIGS.

As shown in FIG. 1, a duct connection structure (hereinafter simply referred to as a "duct connection structure") for a kiln inlet dust collecting device according to the present embodiment is a coke production facility, and more specifically, a kiln entrance to coke oven. It is formed in the dust collector. Here, before demonstrating each structure of a duct connection structure, a coke manufacturing facility is demonstrated.

As shown in FIG. 1, the coke production equipment includes a coke oven 81 in which a plurality of carbonization chambers 811,... (Only one is shown in FIG. 1) for drying the raw material coal are formed in parallel. And a charging vehicle 82 for injecting coal into the carbonization chamber 811 from above the carbonization chamber 811. In addition, the plurality of carbonization chambers 811,... Are each formed in elongate shape and are formed in parallel in the width direction (horizontal direction orthogonal to the length direction).

The coke production equipment includes a coke extruder 83 (coke coke mover) that extrudes the coke that has been carbonized into the extrusion ram 831 from one kiln inlet of the carbonization chamber 811, and the coke extruded and exited from the other kiln inlet. And a coke guide car 84 (coke oven mover) for introducing the gas by a guide device 841 (lattice device).

Moreover, the coke manufacturing equipment is equipped with the damping apparatus 85 which dust-proofs the impregnated gas conveyed from the coke extruder 83 via the duct connection structure 1. In addition, the coke manufacturing facility is provided with the bucket trolley 86 which receives the coke derived from the coke guide car 84 as the bucket 861.

The coke extruder 83 is provided with an extruder main body 833 which moves on the track 832 (ground) along a direction in which the carbonization chambers 811,... Are formed in parallel (hereinafter also referred to as a "moving direction"). . Moreover, the coke extruder 83 transfers the dust-collecting hood 834 for collecting the dust-containing gas which arises from the kiln inlet of the carbonization chamber 811, and the dust-containing gas collected by the dust-collecting hood 834 to a downstream installation. A gas phase duct 835 is provided. In addition, the dust collection hood 834 and the gas phase duct 835 are being fixed to the extruder main body 833.

The cock guide vehicle 84 includes a guide vehicle body 843 that moves on the track 842 (ground) along the direction in which the carbonization chambers 811,... Are formed in parallel. The coke guide car 84 is collected by a dust collecting hood 844 and a dust collecting hood 844 for collecting the dust containing gas generated from the kiln mouth or the guide device 841 or the like of the carbonization chamber 811. An onboard duct 845 for conveying the impregnated gas to the downstream facility is provided. In addition, the dust collection hood 844 and the vehicle duct 845 are being fixed to the guide vehicle main body 843.

The vibration damping apparatus 85 is connected to the duct connection structure 1 via the suction means 851 (for example, a blower) and the connection pipe 852 for sucking a gas containing, and is sucked by the suction means 851. Processing means 853 for processing the sucked impregnated gas. Moreover, the damping apparatus 85 is being fixed to the ground. Moreover, the dust collection hood 834, the gas phase duct 835, the duct connection structure 1, and the vibration damper 85 comprise the kiln inlet dust collector of coke oven.

The duct connection structure 1 which concerns on this embodiment is arrange | positioned along the direction (A positive arrow direction of FIG. 2) in which the carbonization chambers 811, ... are formed in parallel, as shown to FIGS. The liquid rod duct 2 in which (X) is filled inside and the moving duct 3 which move along the direction in which the carbonization chambers 811, ... are formed in parallel are provided. And the duct connection structure 1 is comprised so that the connection state of the liquid sealing duct 2 and the moving duct 3 may be continuously maintained even if the moving duct 3 moves.

The liquid rod duct 2 is a liquid tank 21 arranged along the moving direction and filled with the liquid X therein, and a gas tank arranged along the liquid tank 21 (moving direction) and blocked from the outside. (Iii) 22 and a gas communication section 23 for communicating the liquid tank 21 and the base 22 with each other. In addition, the liquid rod duct 2 is fixed to the ground. In addition, the liquid tank 21 is filled with liquid X on the lower side, and filled with gas on the upper side, and the whole of the base tank 22 and the gas communication part 23 is filled with gas.

The liquid tank 21 is arranged along the direction of movement and the top tank 211 is opened upward, the rear tank 212 is arranged along the tank 211 and cut off from the outside of the liquid rod duct 2, and the roll tank The liquid communication part 213 which communicates the lower side of 211 and the lower side of the rear bath 212 is provided. And the liquid tank 21 is filled with the liquid communication part 213 by the liquid X (water-sealed), and is the back tank 212 (specifically, the gas which fills the upper side of the back tank 212). Is blocked from the outside of the liquid rod duct 2.

The base 22 is equipped with the connection port 221 connected to the connection pipe 852 of the vibration suppression apparatus 85 on the upper side, in order to convey the vibration-containing gas Y to the vibration suppression apparatus 85. Moreover, the base 22 is in communication with the upper side of the rear tank 212 of the liquid tank 21 via the gas communication part 23. Specifically, the gas communicating part 23 communicates the upper side of the base 22 with the upper side of the rear bath 212.

Therefore, before the impregnated gas Y conveyed to the base 22 is conveyed to the connection pipe 852, even if dust falls from the impregnated gas Y by gravity separation, it will be in the lower side of the base 22. It will be deposited. Thereby, it is possible to prevent dust from falling into the liquid X of the liquid tank 21. In addition, not only the case where the space | volume (volume) is set so that dust may be gravity-separated like the present embodiment, as for this base 22, a small amount of dust is isolate | separated by gravity separation and the downward side is removed. The deposition gas Y may be set to a space (volume) in which the impregnated gas Y can stay for a predetermined time.

The moving duct 3 is equipped with the cylindrical duct main body 31 connected so that it may communicate with the gaseous-phase duct 835 of the coke extruder 83 in a base end side. Moreover, the moving duct 3 is equipped in the liquid rod duct 2, and is provided in the front end side with the cylindrical connection part 32 connected to the liquid rod duct 2. As shown in FIG. In addition, the connecting portion 32 is connected to communicate with the duct body 31.

While the duct main body 31 is arranged along the up-down direction, the tip end side is formed to be long along the moving direction. Specifically, the duct main body 31 is formed such that the proximal end is formed in a substantially rectangular shape, and the distal end side is formed elongate along the moving direction, and gradually extends in the moving direction from the proximal end toward the distal end side.

The connection part 32 is moved inward for conveying the impregnated gas Y conveyed from the coke extruder 83 via the duct main body 31 toward the vibration suppression apparatus 85 (in the direction of arrows C and D in FIG. 3). It is provided with the cylindrical duct part 321 made to flow. And the connection part 32 is equipped with the flow path parts 322 and 322 extended in a cylindrical shape along a movement direction, in order to distribute the liquid X inside. Moreover, each flow path part 322 is arrange | positioned so that it may protrude from the duct part 321 in the direction orthogonal to a movement direction.

Moreover, the connection part 32 has the protrusion part 323,323 which protrudes from the duct part 321 in the direction orthogonal to a movement direction, and extends along a movement direction, below the flow path part 322. To be provided. In addition, while the connection part 32 is extended so that the liquid X in the liquid rod duct 2 may pass, the connection part 32 is arrange | positioned so that the lower side may be immersed in the liquid X in the liquid rod duct 2.

The duct part 321 is a sharp part at each end part in the moving direction, in order to suppress that the liquid X in the liquid rod duct 2 rises and falls as the moving duct 3 moves. 321a and 321a are provided. Moreover, the duct part 321 is the duct base part 321b arrange | positioned in the rolling tank 211 of the liquid tank 21, the duct edge part 321c arrange | positioned in the back tank 212 of the liquid tank 21, and the liquid tank 21. Disposed in the liquid communication portion 213, and having a duct connecting portion 321d connecting the duct base 321b and the duct end 321c.

Specifically, the duct part 321 extends from the upper side of the rolling tank 211 until it reaches the upper side of the rear tank 212 via the liquid communication part 213. In this embodiment, the duct part 321 is formed in substantially U shape, and the connection part 32 is also called "U-shaped duct" by this. And although the duct part 321 moves, although the moving duct 3 moves, the gaseous-phase duct 835 of the coke extruder 83 and the vibration damper 85 communicate, ie, the duct main body 31 and the after-joint, The state where the upper side of 212 communicates with each other can be maintained.

The duct base 321b is formed long along the movement direction. Moreover, while the duct base 321b is arrange | positioned along the up-down direction, it is arrange | positioned in the substantially center of the width direction of the roll 211.

The duct end 321c is formed elongate along the moving direction. Moreover, while the duct edge part 321c is arrange | positioned along the up-down direction, it is arrange | positioned in the substantially center of the width direction of the rear bath 212. As shown in FIG.

The duct connection part 321d is formed in circular arc shape, and connects the lower side of the duct base 321b and the lower side of the duct end 321c so that the duct base 321b and the duct end 321c may communicate. The lower side of the duct base 321b, the lower side of the duct end 321c, and the entire duct connecting portion 321d are disposed in the liquid X. As shown in FIG.

Each flow path part 322 presses the liquid press part 322a arrange | positioned above the connection part 32, in order to press the liquid X in the liquid rod duct 2 which rises as the moving duct 3 moves. Equipped. In addition, each flow path portion 322 moves in order to classify the liquid X into the inner side (between the duct portion 321) and the outer side (between the liquid tank 21) as the moving duct 3 moves. It is provided with the sorting part 322b arrange | positioned along this.

Moreover, each flow path part 322 connects the connection part 322c which connects the flow part 322b and the duct part 321, in order to form the closed space by the liquid press part 322a and the flow part 322b. Equipped. Therefore, in this embodiment, the liquid press part 322a comprises the upper part of the flow path part 322, the dividing part 322b comprises the side part of the flow path part 322, and the connection part 322c is the flow path. The lower part of the part 322 is comprised.

Moreover, the flow path parts 322 and 322 are arrange | positioned so that an axial center direction may follow a movement direction, and a pair is formed in the both sides of the width direction of the duct base 321b. And each flow path part 322 is arrange | positioned so that the lower side of the dividing part 322b and the whole of the connection part 322c may be located in the liquid X in the state in which the liquid X (liquid surface X1) was stopped. It is. In this embodiment, each flow path part 322 is formed so that a cross section may become rectangular shape.

The liquid press part 322a is arrange | positioned so that it may protrude from the duct part 321 in the direction (width direction) orthogonal to a movement direction. Moreover, the liquid press part 322a is formed in elongate flat plate shape, and is arrange | positioned so that a longitudinal direction may follow a moving direction. And the liquid press part 322a is arrange | positioned so that it may become parallel to the liquid surface X1 in the state in which the liquid X (liquid surface X1) was stopped.

The dividing part 322b is arrange | positioned so that it may protrude downward from the liquid press part 322a. Moreover, the fractionation part 322b is formed in elongate flat plate shape, and is arrange | positioned so that a longitudinal direction may follow a moving direction. The dividing section 322b is arranged to be orthogonal to the liquid pressing section 322a and is connected to the distal end of the liquid pressing section 322a at the upper end.

The connection part 322c is arrange | positioned so that it may protrude from the duct part 321 in the direction (width direction) orthogonal to a movement direction. Moreover, the connection part 322c is formed in elongate flat plate shape, and is arrange | positioned so that a longitudinal direction may follow a moving direction. And the connection part 322c is arrange | positioned so that it may become parallel to the liquid press part 322a (that is, arrange | positioned so as to be orthogonal to the flow part 322b), and is connected to the lower end part of the flow part 322b at the front-end | tip part.

Each protrusion 323 is arrange | positioned so that it may protrude from the duct part 321 in the direction (width direction) orthogonal to a movement direction. Moreover, each protrusion part 323 is formed in elongate flat plate shape, and is arrange | positioned so that a longitudinal direction may follow a moving direction. And each protrusion part 323 is arrange | positioned so that it may become parallel to the liquid press part 322a and the connection part 322c. In addition, the flow path part 322 (liquid holding part 322a or the connection part 322c) and each protrusion part 322 are set so that the quantity which protrudes from the duct part 321 may become substantially the same.

As mentioned above, according to the duct connection structure 1 and the moving duct 3 which concern on this embodiment, the lower side of the connection part 32 arrange | positioned in the liquid rod duct 2 is connected to the liquid X in the liquid rod duct 2. In the state of being immersed, the moving duct 3 moves in the moving direction. And the liquid press part 322a arrange | positioned above the connection part 32 protrudes in the direction orthogonal to a moving direction.

Thereby, when the liquid X (liquid level X1) in the liquid rod duct 2 rises as the moving duct 3 moves, the liquid X which rises to the lower surface of the liquid press part 322a can be pressed. have. Therefore, as the moving duct 3 moves, the liquid X in the roll 211 of the liquid rod duct 2 rises excessively or the liquid X in the rear bath 212 of the liquid rod duct 2 falls too much. Can be prevented.

In addition, according to the duct connection structure 1 and the moving duct 3 which concern on this embodiment, the water flow part 322b which protrudes toward the downward side from the liquid press part 322a is arrange | positioned along a movement direction. Thereby, as shown in FIG. 5, as the moving duct 3 moves to a moving direction (E arrow direction of FIG. 5 (a)), the liquid X is classified inside and outside of the fractionation part 322b.

Specifically, the liquid X is formed between the duct portion 321 (duct base 321b) and the dividing portion 322b (in the direction of the F arrow in FIG. 5B), the dividing portion 322b and the liquid tank 21. ) (In the direction of the G arrow in Fig. 5 (b)). Here, a Taylor vortex occurs between the moving flow dividing portion 322b and the fixed liquid tank 21, that is, outside the dividing portion 322b.

As a result, the Taylor vortex becomes a resistance, thereby facilitating the flow of the liquid X to the inside of the flow splitter 322b (between the duct portion 321 and the flow splitter 322b, which move in unison). Therefore, since the flow of the liquid X to the outside of the dividing section 322b is suppressed, the liquid X (liquid surface X1) in the liquid rod duct 2 is suppressed from rising outside the dividing section 322b. As a result, for example, the liquid X can be prevented from flowing out of the liquid tank 21.

Moreover, according to the duct connection structure 1 and the moving duct 3 which concern on this embodiment, the flow path part 322 which protrudes in the direction orthogonal to a moving direction will follow the moving direction of an axial center direction (length direction). It extends in a cylindrical shape. Thereby, even if liquid X flows into the flow path part 322 as the moving duct 3 moves to a moving direction, since the flow path part 322 is blocked by a cylindrical shape, it is the inside of the flow path part 322. The liquid X can be prevented from escaping.

In addition, since the fractionation part 322b constitutes the side part of the flow path part 322, it is possible to promote the flow of the liquid X into the flow path part 322, and the liquid X is the flow path part ( Even if much flows into the inside of 322, since the liquid press part 322a comprises the upper part of the flow path part 322, the liquid X which rises to the liquid press part 322a can be reliably pressed.

In addition, the duct connection structure and moving duct which concerns on this invention are 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 are related to the various modified examples mentioned below, and employ | adopt them in the structure, the method, etc. which concern on said embodiment.

For example, in the duct connection structure and the moving duct which concerns on this invention, the case where water is employ | adopted as the liquid X filled in the liquid rod duct 2 may be sufficient, and the case where various liquids are employ | adopted depending on a situation may be sufficient. Specifically, in the case of corrosion prevention, the case where gasoline or an organic solvent is employ | adopted as liquid (X) may be sufficient.

Moreover, in the duct connection structure 1 and the moving duct 3 which concern on the said embodiment, the flow path part 322 (liquid holding part 322a, the dividing part 322b) is 1 in both sides of the duct base 321b. Although the case where a pair is formed was demonstrated, it is not limited to this case.

For example, the flow path part 322 (liquid press part 322a, the dividing part 322b) may be formed only in one side of the duct base 321b, and is formed only in the duct end 321c. As shown to Fig.6 (a), you may be provided in the both sides of the duct base 321b, and the both sides of the duct edge part 321c, respectively. In other words, the flow path portion (liquid press portion, fractionation portion) is not limited to the number and position of formation.

Moreover, in the duct connection structure 1 and the moving duct 3 which concerns on the said embodiment, the case where the flow path part 322 was formed in the rectangular cross section was demonstrated, It is not limited to this case. For example, the flow path portion may be formed so that the cross section is formed in a triangular shape, another polygonal shape or a semicircular shape.

Moreover, in the duct connection structure 1 and the moving duct 3 which concerns on the said embodiment, the case where the flow path part 322 and the fractionation part 322b were formed was demonstrated, It is not limited to this case, A flow path part ( 322 or the case where the dividing part 322b is not formed may be sufficient. Specifically, the case where the liquid press part 322a is arrange | positioned in flat form may be sufficient, and also the case where the some liquid press part 322a, ... is formed in parallel up and down as shown in FIG.6 (b). . In addition, as shown in FIG.6 (b), the some protrusion part 323, ... may be formed in parallel up and down.

Moreover, in the duct connection structure 1 and the moving duct 3 which concerns on the said embodiment, the case where the liquid press part 322a was arrange | positioned continuously along the moving direction was demonstrated, It is not limited to this case. For example, the liquid pressing portion may be disposed intermittently along the moving direction.

Moreover, in the duct connection structure 1 and the moving duct 3 which concern on the said embodiment, the liquid level X1 of the liquid rod duct 2 is the liquid press part 322a and the connection part 322c in the state in which the liquid X was stopped. Although the case where it sets in the above is demonstrated, it is not limited to this case.

For example, the liquid surface X1 of the liquid rod duct 2 may be set below the connection part 322c in the stopped state. In short, the liquid surface X1 of the liquid rod duct 2 should just be set below the liquid press part 322a in the stopped state. In addition, when the liquid X is set to the lower side than the connecting portion 322c in the stopped state, the connecting portion 322c also functions as a liquid pressing portion.

Moreover, in the duct connection structure 1 which concerns on the said embodiment, although the case where the base 22 extended in the side of the liquid tank 21 was demonstrated, it is not limited to this case. For example, the case may not be formed as shown in FIG. 7, may be the case where it is arrange | positioned above the liquid tank 21, and may be the case where it is arrange | positioned further below.

Moreover, in the duct connection structure 1 which concerns on the said embodiment, the case where the coke extruder 83 and the vibration damper 85 are connected (when the moving duct 3 is connected to the coke extruder 83) was demonstrated. However, it is not limited to this case. For example, the duct connection structure may be sufficient when connecting the coke guide vehicle 84 and the vibration suppression apparatus (when the moving duct 3 is connected to the coke guide vehicle 84).

One… Duct joint structure, 2... Liquid rod duct; Moving duct, 32... Connection 322... Flow path portion 322a... Liquid press, 322b... Classification, X... Liquid

Claims (6)

A moving duct moving along a predetermined direction, and a liquid rod duct disposed along the moving direction in which the moving duct moves, and filled with liquid,
The moving duct is disposed in the liquid bar duct and provided with a connecting portion connected to the liquid bar duct at the tip end side thereof,
In a duct connection structure in which a connection part is arrange | positioned so that the lower side may be immersed in liquid,
The connecting portion includes a liquid pressing portion which is disposed on the upper side and protrudes in a direction orthogonal to the moving direction so as to press the liquid rising as the moving duct moves, and the duct connection for the kiln inlet dust collector of the coke oven characterized by the above-mentioned. Structure. The method of claim 1,
The connection part is a duct for a kiln inlet dust collector having a water jet part which protrudes downward from the liquid press part and is arranged along the direction of movement so as to separate the liquid into the inside and the outside as the moving duct moves. Connection structure. The method of claim 2,
The connecting portion has a flow path portion extending in a cylindrical shape along the moving direction for distributing liquid therein,
The flow path portion is disposed to protrude in a direction orthogonal to the movement direction,
The liquid pressing portion constitutes the upper portion of the flow path portion,
The dividing section is a duct connection structure for a kiln inlet dust collecting device that constitutes the side of the flow path. It is arranged in a liquid rod duct which is disposed along a predetermined direction and filled with liquid, and is provided at the tip side with a connecting portion connected to the liquid rod duct.
In the movement duct arrange | positioned so that the lower side of a connection part may be immersed in a liquid when it moves to the said predetermined direction,
The connecting portion includes a liquid pressing portion which is disposed above and protrudes in a direction orthogonal to the predetermined direction in order to press the liquid rising as the moving portion moves in the predetermined direction. The method of claim 4, wherein
The connecting portion includes a splitter that protrudes downward from the liquid presser and is disposed along the predetermined direction in order to separate the liquid into the inside and the outside as the connection portion moves in the predetermined direction. The method of claim 5, wherein
The connecting portion includes a flow passage portion extending in a cylindrical shape along the predetermined direction to distribute the liquid therein,
The flow path portion is disposed to protrude in a direction orthogonal to the predetermined direction,
The liquid pressing portion constitutes the upper portion of the flow path portion,
The dividing section is a moving duct constituting the side of the flow path section.

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