KR20110004479A - Air supply device and high-temperature particulate cooling facility equipped with same air supply device - Google Patents

Abstract

Provided is an air supply device which is used for cooling high temperature powders such as sintered ore pellets, high temperature clinker, etc., and which has excellent use efficiency and good maintainability. The upper portion of the sealing chamber upper spaces 24i and 24i on the movable side air passage 25 side and the upper portion of the movable side air passage 25 communicate with each other, and the annular air passage 25 communicates in the circumferential direction. In addition, an air damper 81 is provided in each of the connecting air ducts 26, so that the air damper 81 is in a closed state in the light distribution part B, and is opened in the cooling part C. have.

Description

Air supply device and high-temperature particulate cooling facility equipped with same air supply device

The present invention provides an air supply device for supplying air to a carrier that moves a carriage path, and the air supply device includes a sintered ore of high temperature or pelletized light. It relates to a cooling system (hot cooling system for hot grain / lump material) for mounting and cooling the ore) in the carrier.

One of the high temperature granular cooling facilities is a sintered ore cooling installation. The sintered ore cooling equipment is configured to cool the sintered ore by flowing cooling air from the lower side of the carrier to the upper side while placing the sintered ore, which is a high-temperature granular material, on the carrier and moving along a generally circular moving path ( For example, see patent documents 1-3).

In this sintered ore cooling installation, a carrier in which a plurality of troughs for mounting a sintered ore for mounting the sintered ore is placed between the inner circumferential side wall and the outer circumferential side wall along a circular path is arranged to be movable. At the bottom of the trough, a cool-air box is installed, and cooling air is supplied thereto. The stationary circular duct is connected to the air box of each trough through a connecting duct, and the movable circular duct is moved through a water sealing device through the stationary circular duct. It is fitted and connected as possible, and a cooling air supply apparatus is provided through the connecting air duct, and cooling air is supplied.

The water sealing device has an inner circumferential annular sealing chamber and an outer circumferential annular sealing chamber formed in the movable side annular air duct, and a lower end portion is formed in the sealing water in these inner circumferential annular sealing chambers and the outer circumferential annular sealing chamber in the fixed side annular air duct. It consists of a sealed sealing plate.

Below, an example of the above-mentioned sintered ore cooling installation is demonstrated in detail based on FIGS. 9-15.

In FIG. 10, the carrier 1 is provided to be movable along a circular movement path A (carriage path A) shown in FIG. 9. The carrier 1 cools the sintered ore by cooling air while moving the sintered ore from the light feeding unit 8 to the light distribution unit 9 through the cooling unit C. In addition, in the following, the light feeding part 8 (material feed zone 8) and the light distribution part 9 (material discharge zone 9) are combined to supply and discharge part (or atmospheric pressure part) B (feed & discharge zones B, or atmospheric). We will call it zone B). In addition, as shown in FIG. 15, a waste heat recovery zone D may be provided in a portion of the cooling zone C. As shown in FIG.

As shown in FIG. 10, this carrier 1 is composed of a plurality of troughs 7, an inner circular side wall 3, and an outer circular side wall 4. These troughs 7 are arrange | positioned so that a movement is possible through the guide wheel 5a in the pair of left and right guide rails 6a provided along the movement path A, and are connected mutually. The inner circular sidewall 3 and the outer circular sidewall 4 are arranged on the trough 7 by being connected to each other by a connection beam 2, It has side wheel 5b guided by the side rail 6b. Each trough 7 is inclinedly connected to the circular side walls 3 and 4 at the front portion thereof in a downward direction around the horizontal axis. In the light distribution part 9, as shown in FIG. 11, when the guide rail 6a is displaced downward with respect to a horizontal direction, the trough 7 is inclined downward through the guide wheel 5a, and is mounted, The sintered ore can be discharged downward.

As shown in FIG. 12, each trough 7 includes a trough body 11 having guide wheels 5a on both sides of the front portion, and an air box 12 installed at the bottom of the trough body 11. Consists of. In addition, a ventilation plate 13 having a plurality of ventilation holes is arranged on the upper surface of the air box 12. Moreover, the opening part 14 is provided in this air box 12 in the lower part of the inner circular side wall 3, for example. 12 and 13, the movable side annular air duct whose upper surface was opened along the circular movement path A shown in FIG. 9 is shown in the inner circular side wall 3 of the said conveyance body 1 (FIG. 21) is installed. The air box 12 of the trough 7 and the movable side annular air duct 21 communicate with each other via a connecting air duct 26 connected to the opening 14. In this movable side annular air duct 21, the inner side wall portion 22 and the outer side wall portion 23 are formed in a double wall structure by the inner plates 22a and 23a and the outer plates 22b and 23b. An inner circumferential annular sealing chamber 24a and an outer circumferential annular sealing chamber 24b each having an upper surface open are formed. An annular movable side air passage 25 is formed between the inner side wall portion 22 and the outer side wall portion 23 of the movable side annular air duct 21.

And the fixed side annular air duct 31 which covers the whole upper part of this movable side annular air duct 21, and forms the annular fixed side air passage 37 which communicates with the movable side air passage 25 is It is installed. The stationary side annular air duct 31 is formed in a U-shaped cross section whose lower surface is opened by the top plate portion 40 and both side wall portions 32 and 33, and the top plate portion 40 of the cooling portion C. 9 and 10, a plurality of intermediate air ducts 38 are connected to each other from the arc shaped air headers 39 shown in FIGS. 9 and 10, and cooling air is supplied to the fixed side air passage 37. The intermediate air duct 38 is not connected to the light distribution part B (the light distribution part 8 and the light distribution part 9).

The fixed side annular air duct 31 and the movable side annular air duct 21 are connected via the water sealing device 28 as shown to FIG. 12, FIG. This sealing device 28 mounts the mounting flange 35 from the inner circumferential annular sealing chamber 24a and the outer circumferential annular sealing chamber 24b and both side wall portions 32 and 33 of the fixed side annular air duct 31. It is comprised by the water sealing plate 34a, 34b which extended so that the lower end may be submerged below water surface in the annular sealing chamber 24a, 24b of both sides through it. And cover plates 36a and 36b protrude so that the outer side of the annular sealing chamber 24a, 24b may be covered in the upper outer side of each sealing sealing plate 34a, 34b. 12 and 13, reference numeral 24i denotes a sealing chamber upper space on the movable side air passage 25 side.

In addition, the dead plate 42 is attached to the stationary side annular air duct 31 via the expansion joint 41 at a portion other than the intermediate air duct 38, while the inner plate 22a and the outer plate ( At the upper end of 23a, labyrinth sealing plates 43a and 43b whose upper ends are close to the dead plate 42 are attached, and a labyrinth seal is applied.

In addition, the inner and outer circumferential fixing side plates 51a and 51b and the inner and outer circumferential fixing side plates 51a and 51b disposed on the upper end portions of the inner and outer circular side walls 23 and 24 at the upper end of the moving path A are provided. The fixing hood 51 which consists of the fixing top plate 51c connected at the upper end part is arrange | positioned. The exhaust duct 52 is connected to a predetermined position of the fixed hood 51.

In addition, as shown in FIG. 14, a partition plate 47 is provided in the movable side air passage 25 of the movable side annular air duct 21 for each of the connecting air ducts 26 (for each trough 7). have. The upper end of the partition plate 47 (partition plate) is provided with labyrinth sealing 43c close to the dead plate 42. As a result, the movable side air passage 25 is partitioned in the circumferential direction (rotation direction) for each section in which the connecting air duct 26 is located. Incidentally, the partition plate as described above is not provided in the sealing device 28.

Moreover, although mentioned above, as shown in FIG. 15, the heat recovery part D may be provided in a part of cooling part C. In addition, as shown in FIG. In this heat recovery part D, the sintered ore is cooled to recover heat from the high temperature air, and then the air is supplied to the annular air duct 31 again as cooling air.

Patent Document 1: Japanese Patent Application Laid-Open No. 4-139380 Patent Document 2: Japanese Patent Application Laid-Open No. 6-257955 Patent Document 3: Japanese Patent Application Laid-Open No. 2000-310489

In the sintered ore cooling installation configured as described above, there are the following problems.

In the light distribution part B, the pressure of the movable side air passage 25 and the air box 12 is atmospheric pressure. On the other hand, the pressure of the movable side air passage 25 in the cooling section C is 300 to 500 mmAq (hereinafter referred to as "cooling differential pressure"), and the structurally the sealing chamber upper space 24i also has the dead plate 42 and the lever. This pressure is maintained by the rinse seal plates 43a, 43b, 43c. However, the length of the dead plate 42 is 10 m or more, and it is difficult in the technical production process to completely seal this length. In addition to deterioration due to long-term use, a gap is generated between the labyrinth sealing plates 43a, 43b, 43c and the dead plate 42, and cooling air in the sealing chamber spaces 24i, 24i leaks. Thereby, cooling efficiency falls.

In addition, the air corresponding to the amount of leakage air leaked from the light distribution part B flows from the movable side air passage 25 into the water seal chamber upper spaces 24i and 24i in the cooling part C. Due to the cooling differential pressure, a severe flow of air toward the light distribution part B is generated in the upper sealing chamber upper spaces 24i and 24i. As a result, the sealing water is waved in the annular sealing chambers 24a and 24b of the light distribution part B, or air leaks from the labyrinth sealing part to the movable side air passage 25 side, and at that time, the annular sealing chamber ( Together with the sealing water in 24a and 24b, water splashes to the movable side air passage 25. As shown in FIG. The sealing water scattered and staying in the movable side air passage 25 is scattered into the trough 7 and attached to the wall surface, the trough 7 and the like of the light distribution part B. When the dust of the sintered ore adheres to and solidifies and grows on the attached water droplets, it becomes wet dust, which causes trouble such as corrosion or blockage of the trough 7 and the like, thereby preventing normal operation. In addition, water sealing performance is deteriorated due to wave or splash of the sealing water, and cooling efficiency is lowered.

In order to cope with the above problem, the level of the upper end of the partition plate 47 and the upper end of the labyrinth sealing plate 43a, 43b, 43c in all compartments can be adjusted so as to almost eliminate the gap with the dead plate 42. There is a need. However, it is difficult to manage a large number of labyrinth sealing plates 43a, 43b, 43c provided in the grand movable side annular air duct 21. Due to the operation of the facility and the aging change, this gap becomes wider and the sealing performance is lowered, but adjustment cannot be made during operation of the facility.

In patent document 3, in order to prevent the trouble by the scattering of sealing water, as shown in FIG. 16, in the light receiving chamber upper space 24i, 24i by the light distribution part B in the movable-side air passage 25 side. It is proposed to supplement compressed air (auxiliary air). That is, the inlet side branch duct (auxiliary air supply means) 61a is branched to the intermediate air duct 38 at the outlet end of the cooling section C, and the tip end of the inlet side branch duct 61a is formed on the light distribution unit ( 9 is connected to the top plate portion 40 of the fixed side annular air duct 31 of the inlet of the inlet, and the outlet side branch duct (auxiliary air supply means) to the intermediate air duct 38 of the inlet end of the cooling unit C ( 61b) is branched, and the front-end | tip part of this exit side branch duct 61b is connected to the top plate part 40 of the fixed side annular air duct 31 of the exit of the light-emitting part 8. As shown in FIG. The auxiliary air supplied from these branch ducts 61a and 61b passes through both side portions of the dead plate 42 between the expansion and contraction joints 41 arranged at intervals, and the inner sealing chamber upper spaces 24i and 24i. Supplied to. As a result, the auxiliary air replenished from the branch ducts 61a and 61b can significantly reduce the speed of the air flowing from the water sealing chamber upper spaces 24i and 24i toward the light distribution part B, thereby reducing the It is possible to prevent scattering.

However, in the method proposed in this Patent Document 3, when the leakage air increases, a large amount of auxiliary air flows out for back pressure. As a result, the leakage air of the cooling air increases, and the balance collapses, causing trouble caused by the leakage air. This happens.

This invention is made | formed in view of the above situation, and is used when cooling high temperature granular materials, such as a sintered or a pellet light, and is excellent in use efficiency, and also maintainability is high, and the high temperature provided with this air supply apparatus. It is an object to provide a granule cooling facility.

In order to achieve the above object, the present invention provides the following air supply device and high temperature granular cooling equipment.

[One]. A plurality of carriers arranged to be movable along a circular movement path, a movable side annular air duct disposed along the movement path and connected to each carrier via a connecting air duct, and disposed along the movement path, A stationary side annular air duct, which is movably fitted to the movable side annular air duct via a water rod device,

The movable side annular air duct and the fixed side annular air duct form an annular air passage,

The sealing device is constituted by an annular sealing chamber disposed along a moving path, and a sealing rod sealing plate whose lower end is immersed in the sealing water in the annular sealing chamber.

In the air supply apparatus provided with the atmospheric pressure part which stops the leakage of the air in a carrier at the predetermined position of a movement path,

The annular air seal chamber upper space on the annular air passage side and the annular air passage on the movable side annular air duct side communicate with each other, and the annular air passage on the movable side annular air duct side communicate with each other in the circumferential direction,

The atmospheric pressure portion includes a connecting air duct closing mechanism for closing the connecting air duct.

[2]. In order to communicate the annular air passage of the movable side annular air duct in the circumferential direction, a partition plate for partitioning the movable side air passage of the movable side annular air duct in the circumferential direction is not provided. Feeding device.

[3]. In order to communicate the annular air passage of the said movable side annular air duct to the circumferential direction, the air cut out in the partition plate which divides the annular air passage of the movable side annular air duct in the circumferential direction is provided, The air of [1] characterized by the above-mentioned. Feeding device.

[4]. The connecting air duct closing mechanism is characterized in that the air damper is installed in the connecting air duct, the air damper is closed at the atmospheric pressure portion, and the air damper is opened at the other than the atmospheric pressure portion. The air supply device in any one of [3].

[5]. [4] The connecting air duct closing mechanism is characterized in that the connecting air duct closing plate is attached to the fixed side annular air duct of the atmospheric pressure portion, and the inlet of the connecting air duct is closed by the connecting air duct closing plate. The air supply device in any one of [3].

[6]. The air supply according to any one of [1] to [5], wherein a foreign matter intrusion preventing plate for preventing foreign matter from entering the annular sealing chamber is provided on the upper side of the annular air passage side. Device.

[7]. The air supply device according to any one of [1] to [6], wherein a foreign matter recovery means for recovering the foreign matter in the annular sealing chamber is provided.

[8]. High temperature granulation which comprises the air supply apparatus as described in any one of [1]-[7], and cools a high temperature granular material using the air supplied from the said air supply apparatus to a conveyance body. Sieve cooling equipment.

[9]. The said conveyance body is comprised by the circular side walls provided in the inside and the outer side, and the some trough which mounts a high temperature granular material in the bottom part of these circular side walls,

The air supplied to the said conveyance body is cooling air which cools the high temperature granular material mounted in the said trough, The high temperature granular material cooling installation as described in [8] characterized by the above-mentioned.

[10]. [8] or [9], further comprising a side rail and a side wheel for guiding and supporting the movement of the carrier from the side, wherein the side wheel has a structure in which the position can be adjusted even during the movement of the carrier. High temperature granule cooling installation described.

Industrial Applicability According to the present invention, it is possible to provide an air supply device having excellent use efficiency and good maintainability, and a high temperature powder granule cooling facility equipped with the air supply device.

1 is an enlarged view of an essential part in Embodiment 1 of the present invention.
2 is an enlarged view of a main part in Embodiment 1 of the present invention.
3 is an enlarged view of an essential part in Embodiment 1 of the present invention.
4 is an enlarged view of an essential part in Embodiment 1 of the present invention.
5 is an enlarged view of a main part in Embodiment 2 of the present invention.
6 is an enlarged view of a main part in Embodiment 2 of the present invention.
7 is an enlarged view of a main part in Embodiment 3 of the present invention.
8 is an enlarged view of a main part in Embodiment 3 of the present invention.
9 is an overall plan view of a conventional example of a sintered ore cooling installation.
10 is a sectional view of principal parts of a conventional example of a sintered ore cooling installation.
11 is a front view of a conventional example of a sintered ore cooling installation.
It is explanatory drawing of the conventional sintered ore cooling installation.
It is explanatory drawing of the conventional sintered ore cooling installation.
It is explanatory drawing of the conventional sintered ore cooling installation.
15 is an overall plan view of another conventional example of a sintered ore cooling installation.
It is explanatory drawing of the conventional sintered ore cooling installation (patent document 3).

Embodiment of this invention is described below, taking the cooling installation of the sintered ore which is a high temperature granular material as an example. In addition, in this specification and drawing, duplication description is abbreviate | omitted by attaching | subjecting the same code | symbol about the component which has substantially the same functional structure.

Embodiment 1

The basic structure of the cooling installation of the sintered ore in Embodiment 1 is the same as that shown in FIG. 9 thru | or 11 mentioned above.

The sintered ore cooling installation of Embodiment 1 has the conveyance body 1 provided so that the movement along the circular movement path A shown in FIG. 9 is possible. The sintered ore is placed on the carrier 1 and cooled by cooling air while moving from the light feeding part 8 to the light distribution part 9 through the cooling part C.

As shown in FIG. 10, the carrier 1 is composed of a plurality of troughs 7, an inner circular side wall 3 and an outer circular side wall 4. The plurality of troughs 7 are arranged so as to be movable through a guide wheel 5a on a pair of left and right guide rails 6a provided along the movement path A, and are connected to each other. The inner circular side wall 3 and the outer circular side wall 4 have side wheels 5b connected to each other by a connecting beam 2 and disposed on the trough 7 and guided to the side rails 6b. . Each trough 7 is connected to the circular side walls 3 and 4 at the front part so that the trough 7 can incline below a horizontal axis.

In the light distribution part 9, since the guide rail 6a is displaced downward, the trough 7 is inclined downward through the guide wheel 5a, and the mounted sintered light can be discharged downward.

As illustrated in FIG. 12, each trough 7 includes a trough body 11 having guide wheels 5a on both sides of the front portion, and an air box 12 installed at the bottom of the trough body 11 ( cool-air box 12). The air box 12 has a ventilation board 13 (louver-board 13) on its upper surface. Moreover, the air box 12 is provided with the opening part 14 (opening 14) in the lower part of the inner circular side wall 3, for example, and the inner circular side wall 3 has an upper surface along the movement path A. As shown in FIG. The opening movable side annular air duct 21 is provided, and the air box 12 and the movable side annular air duct 21 of the trough 7 are connected through the connecting air duct 26 connected to the opening 14. Communicate with each other. In this movable side annular air duct 21, the inner side wall portion 22 and the outer side wall portion 23 are formed in a double wall structure by the inner plates 22a and 23a and the outer plates 22b and 23b. An inner circumferential annular sealing chamber 24a and an outer circumferential annular sealing chamber 24b each having an upper surface open are formed. An annular movable side air passage 25 is formed between the inner side wall portion 22 and the outer side wall portion 23 of the movable side annular air duct 21.

The fixed side annular air duct 31 covers the whole upper part of this movable side annular air duct 21, and forms the annular fixed side air passage 37 which communicates with the movable side air passage 25. As shown in FIG. The stationary side annular air duct 31 is formed in a U-shaped cross section with a lower surface opened by the upper plate portion 40 and both side wall portions 32 and 33. A plurality of intermediate air ducts 38 are connected to the upper plate portion 40 of the cooling unit C from the arc-shaped air header 39, and cooling air is supplied to the fixed side air passage 37. Moreover, the intermediate air duct 38 is not connected to the light distribution part B (light distribution part 8 and light distribution part 9).

The fixed side annular air duct 31 and the movable side annular air duct 21 are connected via the water sealing device 28 as shown to FIG. 12, FIG. This sealing device 28 mounts the mounting flange 35 from the inner circumferential annular sealing chamber 24a and the outer circumferential annular sealing chamber 24b and both side wall portions 32 and 33 of the fixed side annular air duct 31. It is comprised by the water sealing plate 34a, 34b which extended so that the lower end may be submerged below water surface in the annular sealing chamber 24a, 24b of both sides through it. 36a and 36b are the cover plates which protruded so that the outer side of the annular sealing chamber 24a, 24b may be covered in the upper outer side of each sealing sealing plate 34a, 34b.

In addition, the inner and outer circumferential fixing side plates 51a and 51b and the inner and outer circumferential fixing side plates 51a and 51b disposed on the upper end portions of the inner and outer circular side walls 23 and 24 at the upper end of the moving path A are provided. The fixing hood 51 which consists of the fixed upper board 51c connected by the upper end part is arrange | positioned, and the exhaust duct 52 is connected to the predetermined position of this fixing hood 51. FIG.

Moreover, in this embodiment, as shown in FIG. 15, the heat recovery part D is provided in a part of cooling part C, and this heat recovery part D cools the sintered ore to become high temperature. After heat recovery from the air, the air is supplied to the fixed side annular air duct 31 again.

Next, this Embodiment 1 has the following structures.

(A) As shown in FIG. 1 and FIG. 2 which are sectional views of the principal part in Embodiment 1 of this invention, the sealing room upper space 24i, 24i and the movable side air passage by the side of the movable side air passage 25 conventionally are shown. The labyrinth sealing part (dead plate 42 and labyrinth sealing plate 43a, 43b) provided between the 25 is removed, and the sealing room upper space 24i, 24i on the movable side air passage 25 side is removed. The upper portion of the upper portion and the upper portion of the movable side air passage 25 are configured to communicate with each other so that the air can flow.

(B) As shown in FIG. 3, the partition plate 47 and the labyrinth sealing plate 43c which were conventionally provided in the movable side air passage 25 are removed, and the movable side air passage 25 is circumferentially. It is supposed to communicate.

(C) An air damper 81 is provided in each connecting air duct 26.

The air damper 81 is closed in the light distribution part B as shown in Fig. 1 to close the connecting air duct 26, to suppress the flow of cooling air, and at the same time to cool the cooling part C. In FIG. 2, the connection air duct 26 is opened as shown in FIG. 2, and cooling air is supplied to the air box 12. In addition, opening and closing of this air damper 81 is automatically performed by mechanical or electrical control. In addition, although the air damper 81 uses the butterfly type air damper here, it is not limited to this, The other type of air dampers, such as a swing type air damper, can be used.

By the configuration as described above, the movable side air passage 25 and the water seal chamber upper spaces 24i and 24i form a completely communicating annular air duct with no partition in the circumferential direction, and at the same time act as the air damper 81. Since the leakage of air in the light distribution part B is reliably suppressed, the pressure difference between the light distribution part B and the cooling part C is eliminated, and the supply light distribution part B is provided by the cooling part C in the movable side air passage 25. The flow of air to) is lost.

In addition, the movable side air passage 25 and the sealed chamber upper spaces 24i and 24i become completely communicating annular air ducts without partitions in the circumferential direction, and the movable side air passage 25 and the sealed chamber upper spaces 24i and 24i. The pressure of) will also be the same on the circumference.

In addition, since the pressure difference in the circumferential direction in the movable side air passage 25 and the sealing chamber upper spaces 24i and 24i does not occur, the circumference is performed in the movable side air passage 25 and the sealing chamber upper spaces 24i and 24i. No air flow in the direction occurs. As a result, the flow of air from the water seal chamber upper spaces 24i and 24i to the movable side air passage 25 in the light distribution part B does not occur.

As a result, generation | occurrence | production of the troubles, such as corrosion of the trough 7 and the fall of cooling efficiency by the scattering of the sealing water from the annular sealing chamber 24a, 24b, is prevented. In addition, the air damper 81 provided in the connecting air duct 26 is easier to maintain and maintain than the conventional labyrinth sealing unit (dead plate 42 and labyrinth sealing plate 43a, 43b, 43c). The maintenance is good. In addition, since the intermediate air duct 38 can be provided also at the entrance side and exit side of the light distribution part B, which has conventionally been unable to install the intermediate air duct 38 due to the dead plate 42, The equipment scale can improve the cooling capacity as it is.

In the heat recovery section D, the sintered ore is cooled and heat is recovered from the high temperature air, and then the air is supplied as cooling air again. Therefore, foreign matter such as dust of the sintered ore is mixed in the cooling air. There are many cases. If such foreign matter enters and deposits into the annular sealing chambers 24a and 24b, the sealing performance deteriorates due to damage to the sealing seal plates 34a and 34b. Therefore, as shown in FIG. 4, foreign matter mixed in the cooling air is sealed in the upper chamber space between the upper end of the inner plates 22a and 23a of the annular sealing chambers 24a and 24b and the mounting flange 35. It is preferable to install a foreign matter intrusion preventing plate (interference plate) 85 in the upper part of the sealing room upper space 24i, 24i to prevent invasion into the annular sealing room 24a, 24b via the 24i, 24i. desirable. Of course, in addition to the heat recovery part D, when the foreign matter is mixed in the cooling air supplied, the foreign matter intrusion preventing plate 85 may be provided in the same manner.

In addition, in the case where foreign matter such as dust enters and accumulates in the annular sealing chambers 24a and 24b, it is necessary to provide a suction device (not shown) for sucking and collecting the foreign matter from the annular sealing chambers 24a and 24b. desirable. It is good to make the installation position of the suction apparatus into the light distribution part B which has a space.

If the positional relationship between the side rails 6b and the side wheels 5b provided to guide the running of the trough 7 from the side is not appropriate, the running of the trough 7 is shifted from the circle and shifted unevenly. Then, the movable side annular air duct 21 which is connected to the trough 7 via the connecting air duct 26 also rotates. As a result, the relative relationship between the annular sealing chambers 24a and 24b provided in the movable side annular air duct 21 side, and the sealing rod sealing plates 34a and 34b provided in the fixed side annular air duct 31 side. Large deviation occurs in the water-sealed performance. In order to prevent this, it is necessary to adjust the gap between the side rail 6b and the side wheel 5b, which are the causes of the uneven driving, but since the liner adjustment is conventionally fixed, it can be adjusted only at the stop, so that the rotation state is checked. It was not possible to make adjustments while driving while making accurate adjustments.

Therefore, here, the side wheel 5b is made the structure which can be adjusted with a screw jack. As a result, the position of the side wheels 5b can be adjusted even during operation, and the rotation of the annular sealing chambers 24a and 24b can maintain a high roundness, thereby preventing deterioration of the sealing performance.

Embodiment 2

Although Embodiment 2 is basically the same structure as Embodiment 1 mentioned above, in Embodiment 1, the partition board which was conventionally installed in the movable side air passage 25 by making the movable side air passage 25 communicate in the circumferential direction In the second embodiment, a part of the conventional partition plate 47 is cut off, and the guiding function of the cooling air is left while communicating the movable side air passage 25 in the circumferential direction.

That is, in this Embodiment 2, as shown in FIG. 5, FIG. 6 which is the principal part sectional drawing in this embodiment, the partition side board 47a which cut out the upper part of the conventional partition board 47 is provided, and a movable side air path is provided. (25) is communicated in the circumferential direction.

In addition, although the upper part of the conventional partition plate 47 is cut out in FIG. 5, FIG. 6, you may provide the hole cut out in a part of the conventional partition plate 47. FIG.

Embodiment 3

Although Embodiment 3 is basically the same structure as Embodiment 1 mentioned above, in Embodiment 1, it is a means to close the connection air duct 26 in the light distribution part B, and air is connected to the connection air duct 26. FIG. In the third embodiment, in which the damper 81 is provided, the connecting air duct closing plate is attached to the fixed side annular air duct 31 in the light distribution part B, and the connecting air duct closing plate is connected. The inlet of the air duct 26 is closed.

That is, in the third embodiment, as shown in Figs. 7 and 8 which are cross-sectional views of the main parts of the present embodiment, the lock nut is attached to the upper plate portion 40 of the fixed side annular air duct 31 in the light distribution part B. A connecting air duct closing plate (dead plate) 91 is attached to the lower end of the rod and dead plate height indicator 92a fixed by 92b, and the inlet of the connecting air duct 26 is connected by the dead plate 91. I am trying to close it. The inlet of the connecting air duct 26 is connected to the connecting air duct 26 by the lock nut 94b in order to increase the leak-inhibiting effect when the inlet of the connecting air duct 26 is closed by the dead plate 91. And a seal ring 93a and a grand seal 93b attached to the upper end of the rod-and-sealing ring level gauge 94a fixed by the counter spring 94c.

In addition, 92c in FIG. 7 is a sealing mechanism between the rod 92a and the upper plate part 40, and 94d in FIG. 7 is a sealing mechanism between the rod 93a and the connecting air duct 26. In addition, in FIG.

In addition, the height position of the dead plate 91 can be adjusted to an appropriate position by the rod 92a and the lock nut 92b, and the height position of the sealing ring 93a is connected to the rod 94a and the lock nut 94b. Can be adjusted to an appropriate position.

In addition, as shown in FIG. 8, an inlet guide roll 95 is provided at the front end of the dead plate 91 to the light distribution part B, whereby the dead plate 91 is dead due to the movement of the connecting air duct 26. The plate 91 can smoothly close the inlet of the connecting air duct 26.

As a result, also in this Embodiment 3, the movable air chamber 25 can obtain the effect similar to Embodiment 1 by forming the complete communication annular air duct without a partition plate.

Moreover, although the heat collection | recovery part D is provided in the said Embodiment 1-3, it cannot be overemphasized that this invention is applicable also when the heat recovery part D is not provided.

In addition, although the fixed side annular air duct 31 covers the movable side annular air duct 21 from upper direction in the said Embodiment 1-3, this invention is the movable side annular air duct (as patent document 1). It is also applicable in the case where 21) covers the stationary side annular air duct 31 from above.

In addition, in these Embodiments 1-3 which do not have the sealing function by a labyrinth sealing part, it is very effective to prevent the fall of water-sealing performance by making the bracket structure which can adjust the position of the said side wheel 5b by a screw jack. have. The bracket structure which can adjust the position of the side wheel 5b can be applied to the sintered ore cooling installation (for example, patent documents 1-3) provided with the same sealing mechanism other than this embodiment 1-3. .

In addition, although the cooling installation of a sintered ore was demonstrated here as an example, this invention is applicable also to the cooling installation of other high temperature granules, such as a pellet and a high temperature clinker.

As mentioned above, although preferred embodiment of this invention was described referring an accompanying drawing, this invention is not limited to this example. It will be apparent to those skilled in the art that various modifications or modifications can be conceived within the scope of the technical idea described in the claims, and they are naturally included in the technical scope of the present invention.

A travel path, B rapid distribution part, C cooling part, D array recovery part
1 carrier, 2 connecting beams, 3 inner circular sidewalls
4 outer circular sidewalls, 5a guide wheel, 5b side wheel
6a guide rail, 6b side rail, 7 trough
8 light distribution section, 9 light distribution section, 11 trough body
12 air boxes, 13 vents, 14 openings
21 Annular air duct on the movable side
22 inner sidewall
22a inner sidewall portion inner plate, 22b inner sidewall portion outer plate
23 Outer side wall
23a outer sidewall portion inner plate, 23b outer sidewall portion outer plate
24a inner annular sealing room, 24b outer annular sealing room, 24i upper sealing room
25 Movable side air passage, 26 connecting air duct, 28 water seal
31 Fixed side annular air duct, 32, 33 side wall
34a, 34b sealing seal plate, 35 mounting flange
36a, 36b cover plate, 37 fixed side air passage
38 medium air duct, 39 arc air header
40 tops, 41 expansion joints
42 dead plates, 43a, 43b, 43c labyrinth sealing plates
47 partition plate (conventional), 47a partition plate (this invention)
61a, 61b branch duct
81 Air Damper, 85 Debris Entry Plate, 91 Dead Plate
92a rod and dead plate height indicator, 92b lock nut
92c sealing mechanism, 93a sealing ring, 93b gland sealing
94a rod and seal ring level meter, 94b lock nut
94c Disc Spring, 94d Sealing Mechanism

Claims (10)

A plurality of carriers arranged to be movable along a circular movement path, a movable side annular air duct disposed along the movement path and connected to each carrier via a connecting air duct, and disposed along the movement path, A stationary side annular air duct, which is movably fitted to the movable side annular air duct via a water rod device,
The movable side annular air duct and the fixed side annular air duct form an annular air passage,
The sealing device is constituted by an annular sealing chamber arranged along a moving path and a sealing rod sealing plate whose lower end is locked in the sealing water in the annular sealing chamber,
In the air supply apparatus provided with the atmospheric pressure part which stops the leakage of the air in a carrier at the predetermined position of a movement path,
The annular sealing chamber upper space on the annular air passage side and the annular air passage on the movable side annular air duct side communicate with each other,
The annular air passage on the movable side annular air duct side communicates in the circumferential direction,
The atmospheric pressure portion includes a connecting air duct closing mechanism for closing the connecting air duct. The method of claim 1,
And a partition plate for partitioning the movable side air passage of the movable side annular air duct in the circumferential direction so as to communicate the annular air passage of the movable side annular air duct in the circumferential direction. The method of claim 1,
And a cutout portion is provided in a partition plate that divides the annular air passage of the movable side annular air duct in the circumferential direction so as to communicate the annular air passage of the movable side annular air duct in the circumferential direction. 4. The method according to any one of claims 1 to 3,
In the connecting air duct closing mechanism, an air damper is installed in the connecting air duct, the air damper is closed at the atmospheric pressure part, and the air damper is opened at a portion other than the atmospheric pressure part. . 4. The method according to any one of claims 1 to 3,
The connecting air duct closing mechanism is characterized in that the connecting air duct closing plate is attached to the fixed side annular air duct of the atmospheric pressure portion, and the inlet of the connecting air duct is closed by the connecting air duct closing plate. . The method according to any one of claims 1 to 5,
A foreign matter intrusion preventing plate for preventing foreign matter from entering the annular sealing chamber from the annular air passage is provided above the annular air passage side. The method according to any one of claims 1 to 6,
An air supply apparatus, characterized in that a foreign matter recovery means for recovering foreign matter in the annular sealing chamber is provided. The high temperature granular material is cooled using the air supply apparatus in any one of Claims 1-7 using the air supplied from the said air supply apparatus to a conveyance body. Granular Cooling Equipment. The method of claim 8,
The carrier is composed of circular sidewalls provided on the inner side and the outer side, and a plurality of troughs for mounting the high-temperature granular material at the bottom of the circular sidewalls,
The air supplied to a conveyance body is cooling air which cools the high temperature granular material mounted in the trough, The high temperature granular material cooling installation characterized by the above-mentioned. The method according to claim 8 or 9,
A side rail and side wheel which guide and support the movement of a carrier body from the side, The said side wheel becomes the structure which can adjust a position even while a carrier body moves, The high temperature granule cooling facility characterized by the above-mentioned.

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