JP7296034B2 - Sealing device and sintering machine - Google Patents

Description

The present invention relates to a sealing device for sealing between two members that are spaced apart and move relative to each other, and to a sintering machine equipped with such a sealing device.

Various sealing devices have been proposed for sealing between two members that move relatively. For example, Japanese Unexamined Patent Application Publication No. 2009-68721 describes a seal that seals between an air chamber and a cooling trough moving above the air chamber with a curved flexible elastic plate in a sinter cooler. An apparatus is disclosed.

Japanese Unexamined Patent Application Publication No. 2002-372377 discloses a sealing portion that seals between a sintering raw material packed bed of a sintering machine and a pressurized air blower provided thereon. The seal portion has a seal portion main body in which an elastic rubber body having a U-shaped cross section is formed into a ring shape in a plan view, and a wear-resistant chip spread over the circular arc-shaped peripheral surface of the seal portion main body.

Japanese Patent Application Laid-Open No. 11-281261 discloses an air seal device installed on the supply/discharge side of a sintering machine. This air seal device comprises a seal plate under the pallet on which the raw material for sintering is placed, a leaf spring connected to the seal plate to allow the leaf spring to follow the pallet, and an adjusting rod to adjust the follow-up amount of the leaf spring.

Japanese Patent Application Laid-Open No. 2015-197228 discloses a water-sealing device for a rotary sintered ore cooling device. A water seal device has a water seal box provided with a movable side partition plate and a fixed side partition plate. A stainless steel wire plate seal seals between the movable side partition plate and the fixed side partition plate.

Japanese Patent Application Laid-Open No. 2009-68721 Japanese Patent Application Laid-Open No. 2002-372377 JP-A-11-281261 JP 2015-197228 A

In a sealing device that seals between two members that are separated from each other and move relative to each other, the distance between the two members often varies as the two members move relative to each other. The sealing device is required to follow this variation in distance.

SUMMARY OF THE INVENTION An object of the present invention is to provide a sealing device and a sintering machine that are capable of following changes in the distance between two members that are separated from each other and move relative to each other.

A sealing device according to an embodiment of the present invention includes a first member, a second member that moves relative to the first member while being separated from the first member, the first member and the second member. a sealing member disposed between and fixed to the first member and slidably contacting the second member. The first member, the second member and the sealing member are configured to separate two spaces having different pressures. The first member and the second member move relative to each other in a direction parallel to the sliding surface between the second member and the seal member. The sealing member extends from the first member to reach the second member, bends from a portion in contact with the second member, separates from the second member, and enters a space having a higher pressure among the two spaces. extend towards. A tip of the sealing member is located in the high-pressure space.

According to the disclosure of the present application, it is possible to improve followability to variation in the distance of the gap between two members that are separated from each other and relatively move.

FIG. 1 is a side view showing the structure of the sealing device of this embodiment. 2 is a perspective view of the sealing device shown in FIG. 1. FIG. FIG. 3 is a side view showing a modification of the sealing member. FIG. 4 is a side view showing another modification of the sealing member. FIG. 5 is a side view showing another modification of the sealing member. FIG. 6 is a side view showing another modification of the sealing member. FIG. 7 is a side view showing another modification of the sealing member. FIG. 8 is a diagram showing a configuration example of a sintering machine. 9 is a perspective view of the vicinity of the end of the sintering machine shown in FIG. 8 on the waste ore side. FIG. 10 is a side view of the pallet truck passing over the dead plate as seen from the width direction. 11 is a cross-sectional view taken along line XI-XI in FIG. 10. FIG. FIG. 12 is a cross-sectional view of the girder beam portion of the pallet truck. FIG. 13 is a cross-sectional view showing a configuration example of a heat treatment furnace. 14 is a side view of the portion including the opening shown in FIG. 13 as viewed in the direction of arrow A. FIG. FIG. 15 is a cross-sectional view showing an example in which the pressure inside the container is higher than the pressure outside the container. FIG. 16 is a cross-sectional view showing a configuration example of a continuous firing kiln. 17 is a side view of the portion including the opening shown in FIG. 16 as viewed in the direction of arrow A. FIG.

The inventors have studied how to improve the ability to follow changes in the distance of the gap between the two members in a sealing device that seals between two members that move relative to each other. In the course of the study, it was found that many sealing devices have a structure that separates two spaces having different pressures. In consideration of this pressure difference, the inventors have studied the configuration of a sealing device that improves followability. As a result, the following configurations of the embodiments were conceived.

(Configuration 1)
A sealing device according to an embodiment of the present invention includes a first member, a second member that moves relative to the first member while being separated from the first member, the first member and the second member. a sealing member disposed between and fixed to the first member and slidably contacting the second member. The first member, the second member and the sealing member are configured to separate two spaces having different pressures. The first member and the second member move relative to each other in a direction parallel to the sliding surface between the second member and the seal member. The sealing member extends from the first member to reach the second member, bends from a portion in contact with the second member, separates from the second member, and enters a space having a higher pressure among the two spaces. extend towards. A tip of the sealing member is located in the high-pressure space.

In configuration 1 above, the seal member between the two spaces is pushed from the high-pressure space to the low-pressure space due to the pressure difference between the two spaces. When the seal member is pressed, the curved portion of the seal member is pressed against the second member. When the distance between the first member and the second member varies, the curved portion of the sealing member is pressed against the second member, so the sealing member easily follows the second member. Therefore, it is possible to improve the followability to the variation in the distance of the gap between the two members. The direction of movement of the first member and the second member is not limited to a direction that is strictly parallel to the sliding surface of the second member with the seal member. . Further, the sliding surface of the second member with the seal member may be a flat surface or a curved surface.

(Configuration 2)
In configuration 1 above, the seal member may be configured by stacking a plurality of curved plates, and the curved surface of one of the plurality of plates may be in contact with the second member. Thereby, the wear resistance of the seal member can be improved.

(Composition 3)
In configuration 1 or 2 above, the portion of the seal member in contact with the second member may be thicker than other portions. Thereby, the wear resistance of the portion of the seal member that contacts the second member can be enhanced. The thickness of the sealing member is the dimension in the direction perpendicular to the extending direction of the sealing member. Here, the extending direction of the sealing member is the direction extending from the first member to the second member, and further away from the second member and extending toward the space.

(Composition 4)
In any one of configurations 1 to 3 above, the sealing member may include a first sealing member and a second sealing member. The first sealing member extends from the first member to reach the second member, and further curves from a portion in contact with the second member to move away from the second member to provide a space between the two spaces where the pressure is higher. Extending toward the space, the tip of the first sealing member is located in the higher pressure space. The second sealing member extends from the first member to reach the second member, curves from a portion in contact with the second member, and separates from the second member to form a space having a lower pressure among the two spaces. and the tip of the second sealing member is located in the low pressure space.

By including the first sealing member and the second sealing member in this way, the sealing performance of the sealing member is enhanced. Further, even if the pressure levels in the two spaces partitioned by the first member, the second member, and the seal member are reversed, the followability improvement effect due to the pressure difference can be obtained.

(Composition 5)
In any one of the above configurations 1 to 4, the first member is a container having an opening, and the second member is movable between the outside and the inside of the container through the opening. good too. The sealing material extends from the edge of the opening to reach the second member passing through the opening, curves away from the second member from a portion in contact with the second member, and extends from the inside and outside of the container. , may be formed to extend in the direction of higher pressure. In this case, the tip of the sealing member is located in the inside or outside of the container, whichever has the higher pressure.

Thereby, the gap between the opening of the container and the second member passing through the opening can be sealed with the sealing member. Also, the followability of the seal member to the second member passing through the opening can be enhanced.

A container having an opening, which is an example of the first member, is not limited to a specific one. Examples of such a container include, for example, a heat treatment furnace, a surface treatment cleaning hood for painting, a painting hood, and the like.

(Composition 6)
In any one of the above configurations 1 to 4, the second member is a plate-like member that constitutes the upper surface of the box surrounding the space with the lower pressure among the two spaces, and is a plate-like member having an opening. good too. The first member may be a member that constitutes a lower surface of a carriage that moves to a position that closes the opening of the box. The plate member may be formed to extend outward from both ends of the opening in the moving direction of the carriage. The seal member may be configured to contact the plate member when the first member moves over the second member.

Thereby, the space between the lower surface of the carriage and the plate-like member can be sealed by the sealing member. In addition, it is possible to improve the followability of the seal member to the plate member.

The sealing member may include a first sealing member and a second sealing member. The first sealing member extends from the first member and curves toward the traveling direction of the truck, and the second sealing member extends from the first member toward the direction opposite to the traveling direction of the truck. May be curved. As a result, the sealing member can follow the pressure difference better both when the cart enters the box and when it leaves the box.

(Composition 7)
In configuration 6 above, the tip of the sealing member may be configured to be positioned above the lower surface of the first member. As a result, when the first member passes over the second member, the seal member is less likely to hit the second member.

(Composition 8)
A sintering machine equipped with the sealing device of configuration 6 or 7 is also included in the embodiments of the present invention. The sintering machine has a plurality of pallet trucks that move on endless tracks. Each of the pallet trucks includes a plurality of girder beams extending in the width direction and arranged side by side in the transport direction, a pair of side frames supporting both ends of the plurality of girder beams and extending in the movement direction, and the plurality of It has a plurality of great bars spanning the upper part of the girder and arranged in the width direction, and a pair of seal bars attached to the lower surfaces of the pair of side frames so as to move vertically. The sintering machine includes a wind box group composed of a plurality of wind boxes arranged in a moving direction below the pallet truck in a region where the pallet truck loaded with the raw material for sintering moves, and a pair of wear bars arranged in contact with the lower surfaces of the seal bars of the pallet truck and formed to extend in the moving direction; a pair of wear bar supports supporting the pair of wear bars respectively under the pallet truck; a flexible dead plate disposed below the pallet truck and between the pair of wear bars outward in the movement direction from at least one of both ends in the movement direction of the wind box group. . The first member may be the beam, the second member may be the dead plate, and the box may be the wind box.

According to the configuration 8, in the sintering machine, it is possible to improve the followability of the seal member for sealing between the girder beam of the pallet truck and the dead plate to the dead plate.

In configuration 8 above, the seal member may be attached to a lower portion of the girder beam and may be formed to extend below the lower surface of the girder beam. This sealing member can further enhance the sealing performance between the lower surface of the beam and the upper surface of the dead plate.

In configuration 8 above, the girder beam may have a projection that protrudes above the lower surface of the girder beam in the conveying direction or in the direction opposite to the conveying direction. A sealing member may be attached to the protrusion, the sealing member being formed by extending from the protrusion to below the lower surface of the girder beam.

In Configuration 8 above, it is preferable that the protrusion is formed to extend continuously in the width direction. The sealing member may be provided under the projection so as not to protrude beyond the projection in the conveying direction or in the direction opposite to the conveying direction. The projection protects the sealing member from the flow of the sintering exhaust gas.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The same reference numerals are given to the same or corresponding parts in the drawings, and the description thereof will not be repeated.

(Embodiment 1)
FIG. 1 is a side view showing the structure of the sealing device of this embodiment. 2 is a perspective view of the sealing device shown in FIG. 1. FIG. The sealing device comprises a first member 1 , a second member 2 and a sealing member 3 . The second member 2 moves relative to the first member 1 while being separated from the first member 1 . For example, a configuration in which the first member 1 is fixed and the second member moves, or a configuration in which the second member 2 is fixed and the first member 1 moves may be used. Alternatively, both the first member 1 and the second member 2 may be configured to move.

A sealing member 3 is fixed 1 to the first member and contacts the second member 2 . The seal member 3 and the second member 2 are slidably in contact with each other. The second member 2 has a sliding surface that slides on the seal member 3 . The sliding surface of the second member 2 may be flat or curved. In this example, the second member 2 moves relative to the first member 1 in a direction parallel to the sliding surface.

The first member 1, the second member 2 and the sealing member 3 are configured to separate two spaces having different pressures. That is, the first member 1, the second member 2 and the sealing member 3 are positioned between the two spaces H and L having different pressures.

The seal member 3 extends from the first member 1 to reach the second member 2, bends from a portion 3a in contact with the second member 2, and separates from the second member 2 to form a space H having a higher pressure among the two spaces. extending towards. A portion of the seal member 3 that slides on the second member 2 is curved. A tip 3b of the seal member 3 is located in the space H where the pressure is high. A tip 3b of the sealing member 3 is a free end and is not fixed to another member. That is, one end of the sealing member 3 is fixed to the first member 1, and the other end, that is, the tip 3b is not fixed and is positioned in the space H where the pressure is high. With this configuration, the curved portion of the seal member 3 is pressed against the second member 2 due to the pressure difference between the two spaces H and L (arrow F). Therefore, the followability of the seal member 3 to the second member 2 is improved.

For example, when the second member 2 moves to the position indicated by the dashed line T shown in FIG. 1 and then returns to its original position, the sealing member 3 elastically deforms to maintain contact with the second member 2. can be done. That is, the seal member 3 is elastically deformed according to the distance between the first member 1 and the second member 2 . Since the portion of the seal member 3 that slides on the second member 2 is curved, bending stress due to deformation is less likely to concentrate locally. Therefore, deterioration of the follow-up function due to permanent deformation of the seal member 3 is unlikely to occur.

As shown in FIG. 2, the sealing member 3 is a curved plate (sheet) having a J-shaped cross section. The curved inner surface of the sealing member 3 faces the space H where the pressure is high. A curved surface of the seal member 3 contacts the second member 2 in a slidable manner. In the seal member 3, the portion between the first member 1 and the portion 3b in contact with the second member 2 has a convex shape from the space H where the pressure is high toward the space L where the pressure is low. That is, the surface of the seal member 3 that is convex in the direction pushed by the gas in the space H with high pressure contacts the first member 1 . Also, the tip 3 b of the seal member 3 is separated from the second member 2 . Since the convex surface of the seal member 3 is thus pressed against the second member 2 due to the pressure difference, the sealing performance is improved. Furthermore, the seal member 3 is less likely to hit the steps and unevenness of the sliding surface of the second member 2 .

A portion 3a of the seal member 3 in contact with the second member 2 extends linearly. In this example, the direction perpendicular to the extending direction of the portion 3a where the seal member 3 is in contact with the second member 2 is the direction of relative movement of the second member 2 with respect to the first member 1 . Thus, the direction in which the seal member 3 curves from the portion 3a in contact with the second member 2 can be substantially the same as the direction of relative movement of the second member 2 with respect to the first member 1 or the opposite direction thereof. Thereby, followability can be further improved. The direction of relative movement of the second member 2 with respect to the first member 1 is not limited to this, and may be a direction perpendicular to the bending direction of the seal member 3 .

In the example shown in FIG. 1 , the sealing member 3 is attached to the projection of the first member 1 by means of the fastening member 4 . The attachment position and attachment structure of the seal member 3 to the first member 1 are not limited to this. Also, the sealing member 3 may be formed of one or two or more plates of metal or resin. Alternatively, the sealing member 3 may be formed by arranging wire brushes in a plate shape, or by sandwiching a thin plate between wire brushes to form a plate shape. Thermal spraying or the like may be applied to the surface of the portion of the seal member 3 that is in contact with the second member 2 . Thereby, the wear resistance of the seal member 3 can be improved.

FIG. 3 is a side view showing a modification of the seal member 3. FIG. In the example shown in FIG. 3, the sealing member 3 is constructed by stacking a plurality of curved plates. In this example, multiple plates are superimposed over the entire sealing member 3 . One of the plates of the seal member 3 contacts the second member. For example, the plate in contact with the second member 2 may be made of a highly wear-resistant material. The material of the plate forming the seal member 3 is not particularly limited, but metal such as stainless steel or resin may be used. The materials of the plurality of plates forming the seal member 3 may be different.

FIG. 4 is a side view showing another modification of the seal member 3. As shown in FIG. In the example shown in FIG. 4, the seal member 3 is constructed by stacking a plurality of curved plates. A plurality of plates are superimposed on a part of the sealing member 3 . In this example, the portion where the seal member 3 is in contact with the second member 2 is configured by stacking a plurality of plates. As a result, the portion of the seal member 3 in contact with the second member 2 is thicker than the other portions.

FIG. 5 is a side view showing another modification of the sealing member. In the example shown in FIG. 5, the sealing member 3 has a plate 3C fixed to the first member 1 and a rigid body 3D attached to the plate 3C. One end of the plate 3C is fixed to the first member 1, and the rigid body 3D is attached to the other end. The other end is located in the space H where the pressure is high. The plate 3C is elastically deformable. The plate 3C has a curved portion extending curvedly from the first member 1 toward the space H where the pressure is high, and a portion to which the rigid body 3D extending further from the curved portion is attached. A rigid body 3D is attached to the lower surface of the plate 3C. The rigid body 3D has a curved surface opposite to the mounting surface of the plate 3C. A curved surface of the rigid body 3D contacts the second member 2 . As a result, the seal member 3 is curved from the portion 3a in contact with the second member 2, separated from the second member 2, and extended toward the space H where the pressure is high. Further, the tip 3b of the seal member 3 is positioned in the space H where the pressure is high.

In the example shown in FIG. 5, the elastic deformation of the plate 3C and the curved surface of the rigid body 3D enhance the followability, and the rigid body 3D enhances the wear resistance. Although the material of the plate 3C and the rigid body 3D is not particularly limited, it can be metal, for example. In this case, the plate 3C and the rigid body 3D can be joined by welding. Alternatively, the rigid body 3D may be made of resin and attached to the plate 3C with an adhesive or a fastening member.

FIG. 6 is a side view showing another modification of the sealing member. In the example shown in FIG. 6, the sealing member 3 includes a first sealing member 31 and a second sealing member 32. As shown in FIG. The first sealing member 31 extends from the first member 1 to reach the second member 2, and further curves from a portion 31a in contact with the second member 2 to move away from the second member 2 toward the space H where the pressure is high. Extend. The tip 31b of the first seal member 31 is positioned in the space H where the pressure is higher. The second seal member 32 extends from the first member 1 to reach the second member 2, and further curves from a portion 32a in contact with the second member 2 to move away from the second member 2 toward the space L where the pressure is low. Extend. The tip 32b of the second seal member 32 is located in the space L where the pressure is low. In the example shown in FIG. 6, in the sealing member 3, two plates bent in opposite directions are arranged one on top of the other. Note that three or more plates may be stacked and arranged.

In the example shown in FIG. 6, when the pressure levels in the two spaces partitioned by the first member 1, the second member, and the seal member 3 are reversed, the curved portion of the second seal member 32 is moved by the pressure difference. 2 is pressed against member 2 (arrow F2). Therefore, even if the pressure levels of the two spaces are reversed, the followability is improved. At least one of the first sealing member 31 and the second sealing member 32 shown in FIG. 6 may have any of the configurations shown in FIGS.

FIG. 7 is a side view showing a modification of the first sealing member 31 and the second sealing member 32. FIG. In the example shown in FIG. 7, the first sealing member 31 and the second sealing member 32 are common from the first member 1 to the portion 3a in contact with the second member. A first seal member 31 and a second seal member 32 are branched from the portion 3a that contacts the second member. In this way, the first sealing member 31 and the second sealing member 32 may be branched between the first member 1 and the second member 2 .

For example, the plate from the first member 1 to the branch and the plate forming the first seal member 31 and the second seal member 32 ahead of the branch are connected by welding to produce the seal member 3 shown in FIG. can do. Alternatively, the sealing member 3 shown in FIG. 7 can be produced by extrusion molding a resin.

In the example shown in FIG. 7, the sealing member 3 is configured to support a curved plate material forming the sliding surface near the center of the curve. With this configuration, regardless of whether the pressure in the two spaces partitioned by the seal member 3 is high or low, it is possible to exhibit followability due to the pressure difference.

Further, in the example shown in FIG. 7, the plate from the first member 1 to the branch is curved. In this way, by virtue of deformation of the plate from the first member 1 to the branch, the followability of the seal member 3 to the second member 2 can be further enhanced. In particular, followability to variation in the distance between the first member 1 and the second member 2 in the direction perpendicular to the sliding surface of the second member 2 is improved.

(sintering machine)
An example of a sintering machine including a sealing device will now be described. FIG. 8 is a diagram showing a configuration example of the sintering machine 100 in this embodiment. The sintering machine 100 comprises a plurality of pallet trucks 10 arranged adjacent to each other on an endless track K. As shown in FIG. The endless track K includes an upper stage Ku and a lower stage Kd. In the upper stage Ku of the endless track K, a pallet truck 10 loaded with raw materials for sintering moves in the direction indicated by an arrow Y1 from the ore supply side KS, which is upstream, toward the ore discharge side HS, which is downstream. The direction of movement of the upper stage is defined as the y-axis. The x-axis is the width direction, and the z-axis is the vertical direction.

In this specification, in the pallet truck, the direction in which raw materials for sintering are stacked is the top, and the opposite direction is the bottom. The pallet movement direction is the traveling direction of the pallet truck when the pallet truck moves on the track. The width direction is a direction orthogonal to the pallet movement direction and the vertical direction.

A bedding hopper 31, a feed hopper 32, and an ignition furnace 33 are arranged in this order from upstream above the stage Ku on the endless track K. As shown in FIG. The bedding hopper 31 feeds relatively coarse ore fines onto the pallet truck 10 . The iron ore fed from the bedbed ore hopper 31 covers the fire grate that is the bottom (floor) of the raw material storage section of the pallet truck 10 . The ore feed hopper 32 feeds relatively fine fine ore to the pallet truck 10 . Coke is mixed with the fine ore that is fed. The ignition furnace 33 ignites the surface of the sintered ore raw material accommodated in the pallet truck 10 . Due to the ignition, combustion starts from the upper layer of the sintering raw material on the pallet truck 10 . By the time the pallet car 10 reaches the downstream end of the upper tier Ku, combustion reaches the bottom layer of sintering material on the pallet car 10 . At the downstream end of the upper tier Ku, the pallet truck 10 turns over and discharges.

A plurality of wind boxes 21 are arranged below the pallet truck 10 of the upper stage Ku of the endless track K. A plurality of wind boxes 21 constitute a group of wind boxes. A plurality of wind boxes 21 are arranged side by side in the moving direction of the pallet truck 10 . That is, a plurality of wind boxes 21 are provided in an area where a pallet truck loaded with raw materials for sintering moves. The spaces within the plurality of wind boxes 21 are interconnected and isolated from the atmosphere. Pipes 25 and 26 are connected to each of the wind boxes 21 . The space inside the wind box 21 is connected to an induced draft fan 27 through pipes 25 and 26 .

A dead plate 17 is arranged at an upstream end and a downstream end of a wind box group composed of a plurality of wind boxes 21 in the pallet movement direction. A dead plate 17 constitutes the upper surface of the box. The dead plate 17 is a plate-like member extending outward from the end of the wind box group composed of the plurality of wind boxes 21 in the pallet movement direction. The dead plate 17 is a plate that forms the upper surface of the end of the wind box group in the pallet movement direction. The widthwise dimension of the dead plate 17 is the same as or longer than the widthwise dimension of the opening at the end of the wind box group in the pallet movement direction. That is, the dead plate 17 is formed extending in the width direction so as to cover between both width direction ends of the inner space of the wind box group in the pallet movement direction. An opening between a pair of dead plates 17 provided at both ends of the wind box group serves as an opening of the wind box 21 . The dead plate 17 contacts the lower surface of the pallet truck 10 passing over the dead plate 17 . That is, the pallet truck 10 passing over the dead plate 17 moves with its lower surface in contact with the dead plate 17 . As a result, the ends of the wind box group in the pallet movement direction are sealed. The dimension of the dead plate 17 in the pallet movement direction can be made larger than the dimension of the pallet truck 10 in the pallet movement direction, for example.

FIG. 9 is a perspective view of the vicinity of the end of the ore discharge side HK of the wind box group composed of the plurality of wind boxes 21 of the sintering machine 100 shown in FIG. As shown in FIG. 9, a pair of wear bars 13 extending along the pallet moving direction are arranged below the pallet truck 10 on the upper stage of the endless track. The pair of wear bars 13 are spaced apart in the width direction. The widthwise length between the pair of wear bars 13 is substantially the same as the widthwise dimension of the upper opening of the wind box 21 . The wear bar 13 is arranged at a position in contact with a seal bar (described later) attached to the lower surface of the pallet truck 10 .

The wear bar 13 is supported by the wear bar support 12 . The wear bar support 12 includes a base plate on which the wear bar 13 is placed, a vertically extending support portion that supports the base plate, and a bottom portion that supports the lower portion of the support portion. The supporting portion of the weir bar support 12 extends in the movement direction and forms part of the side wall of the closed space of the wind box group.

A dead plate 17 is positioned between the pair of wear bars 13 . In this example, the relative positions of both ends of the dead plate 17 in the width direction and the pair of wear bars 13 are fixed. The dead plate 17 may be supported by the wear bar 13 or may be supported by the wear bar support 12 . Both ends of the dead plate 17 in the width direction are in contact with the pair of wear bars 13 . The dead plate 17 has flexibility. Therefore, the portion between both ends of the dead plate 17 can be elastically deformed so as to be vertically displaced.

As an example, the height of the top surface of the dead plate 17 can be substantially the same as the height of the top surface of the wear bar 13 . A plurality of guide plates 18 are provided at the upstream end of the dead plate 17 in the pallet movement direction. The plurality of guide plates 18 are arranged side by side in the width direction. Each guide plate 18 protrudes from the end of the dead plate 17 in the direction opposite to the moving direction of the pallet. The guide plate 18 extends obliquely downward from the dead plate 17 in a direction opposite to the moving direction of the pallet. The lower surface of the pallet truck 10 entering onto the dead plate 17 is guided onto the dead plate 17 along the slope of the guide plate 18 . When the lower surface of the pallet truck 10 is lower than the upper surface of the dead plate 17 , the lower surface of the pallet truck 10 abuts against the guide plate 18 and advances in the pallet moving direction and is guided onto the dead plate 17 when entering. Note that the guide plate 18 may be omitted.

FIG. 10 is a side view of the pallet truck 10 passing over the dead plate 17 as seen from the width direction. The pallet truck 10 has a pallet frame 20 and side plates 61 mounted on the pallet frame 20 . The pallet frame 20 has a plurality of girder beams 20a, 20b, 20c arranged side by side in the pallet movement direction of the pallet truck 10. As shown in FIG. A great bar 8 spans over two girder beams 20a aligned in the pallet moving direction.

Among the plurality of beams 20a, 20b, and 20c in one pallet truck 10, the sealing members 3 are provided on the beams 20b other than the beams 20a and 20c at both ends in the pallet moving direction. The seal member 3 is slidably in contact with the upper surface of the dead plate 17 when the beam 20b passes over the dead plate 17. - 特許庁The beam 20b corresponds to the first member 1 described above. The dead plate 17 corresponds to the second member 2 described above. Details of the configuration of the seal member 3 will be described later.

As shown in FIG. 10, among the plurality of beams 20a, 20b, and 20c, the frontmost beam 20a in the moving direction of the pallet can be provided with no sealing member. As a result, when the pallet truck 10 enters onto the dead plate 17, the frontmost girder beam 20a is less likely to hit the dead plate 17. - 特許庁Moreover, it is possible not to provide the sealing member on the rearmost beam 20a in the pallet movement direction among the plurality of beams 20a, 20b, and 20c. As a result, similar effects can be obtained when the pallet truck 10 is reversed front to back and used in the opposite traveling direction.

11 is a cross-sectional view taken along line XI-XI in FIG. 10. FIG. In the pallet truck 10 , the pair of side plates 61 are arranged at both ends of the pallet frame 20 in the width direction. A pair of side plates 61 are attached to the upper surface of the pallet frame 20 . A pair of side plates 61 extend upward from the pallet frame 20 . A plurality of great bars 8 are arranged on the pallet frame 20 between the pair of side plates 61 . The pallet frame 20 has a pair of side frames 20b supporting both ends of the beam 20a. The girder 20b is formed extending in the width direction between the pair of side frames 20b. A plurality of great bars 8 are arranged on the girder beams 20a. A plurality of great bars 8 constitute a grate. A pair of wheels 7 are rotatably attached to both ends of the pallet frame 20 in the width direction. Axles 7a of the pair of wheels 7 extend in the width direction. Raw materials for sintering are loaded onto the grate. That is, the raw material for sintering is stored in the space surrounded by the grate of the plurality of great bars 8 and the pair of side plates 1 .

Wheels 7 roll on rails 11 extending in the direction of pallet movement. A pair of wear bars 13 extending in the pallet movement direction and a pair of wear bar supports 12 supporting the pair of wear bars 13 are arranged inside the rails 11 . The wear bar 13 and the wear bar support 12 are arranged below the pallet truck 10 . Two recesses 20F are formed in the lower surface of the pallet frame 20 . The recess 20F extends in the pallet movement direction. The two recesses 20F are spaced apart in the width direction. A pair of seal bars 40 extending in the pallet movement direction is inserted into each of the two recesses 20F. Each of the pair of seal bars 40 is attached to the pallet frame 20 so as to be vertically movable. When the pallet truck 10 is loaded with raw materials and moves, the seal bar 40 moves relative to the weir bar 13 in the pallet movement direction while the lower surface of the seal bar 40 is in contact with the upper surface of the weir bar 13 . That is, the seal bar 40 slides with respect to the wear bar 13 .

A plurality of wind boxes 21 are arranged below the pallet truck 10 . A plurality of wind boxes 21 are arranged side by side in the pallet movement direction, that is, the y direction. A space below the great bar 8 of the pallet truck and between the pair of seal bars 40 , the pair of weir bars 13 , and the pair of weir bar supports 12 is connected to the space in the wind box 21 . Gas in the wind box 21 is sucked by the induced draft fan 27 . The space inside the wind box 21 is connected to an induced draft fan 27 through pipes 25 and 26 . A negative pressure is created in the wind box 21 . That is, the space surrounded by the great bar 8, the pair of seal bars 40, the pair of weir bars 13, and the pair of weir bar supports 12 has a negative pressure. As a result, the gas in the raw material is sucked into the wind box 21 through the grate of the great bar 8, and the air above the raw material is taken into the raw material.

As shown in FIG. 10, the sintering machine 100 includes a push-up device 41 that pushes up the widthwise central portion of the dead plate from below. The push-up device 41 includes a weight 45 and a link 42 that transfers the gravity of the weight 45 to the lower surface of the dead plate 17 . Link 42 is rotatably supported around shaft 44 extending in the width direction. A pressing member 43 is attached to one end of the link 42 so as to be rotatable around an axis extending in the width direction. A weight 45 is suspended from the other end of the link 42 . The pressing member 43 is in contact with the lower surface of the central portion between both ends of the dead plate 17 in the width direction. With this configuration, the gravity of the weight 45 is transmitted to the pressing member 43, and the pressing member 43 presses the lower surface of the central portion of the dead plate 17 in the width direction from below. Two push-up devices 41 are arranged side by side in the pallet movement direction. As a result, two portions of the dead plate 17 spaced apart in the pallet movement direction are pushed up from below by the push-up device 41 .

Note that the configuration of the push-up device 41 is not limited to the configuration shown in FIG. For example, the push-up device 41 may be configured to push up the dead plate 17 by the elastic force of a spring. In this case, the push-up device 41 can include a spring and a transmission member that transmits the elastic force of the spring as a force pushing the dead plate 17 from below.

In the example shown in FIG. 10, the guide plates 18 are provided at both ends of the dead plate 17 in the pallet movement direction, that is, both the upstream end and the downstream end in the pallet movement direction. The guide plate 18u at the upstream end extends obliquely downward from the upstream end of the dead plate 17 in the pallet moving direction toward the direction opposite to the pallet moving direction. The downstream end guide plate 18d extends obliquely downward in the pallet moving direction from the downstream end of the dead plate 17 in the pallet moving direction. Thus, by providing the guide plates 18 at both ends of the dead plate 17 in the pallet moving direction, even when the pallet truck is driven in the direction opposite to the pallet moving direction for repairing the sintering machine, the pallet truck can be operated. The dead plate 17 can be made difficult to hit.

In the example shown in FIG. 10 , a plate member 15 extending downward is provided on the lower surface of the dead plate 17 . The plate member 15 is fixed in close contact with the dead plate 17 . As shown in FIG. 11, a plurality of strip-shaped plate members 15 are arranged side by side in the width direction. This does not hinder the bending of the dead plate in the width direction.

Again referring to FIG. 10 , the lower portion of the plate member 15 is slidably in contact with the end surface member 22 of the wind box 21 . The end member 22 is provided at the end of the wind box group in the pallet movement direction. The end face member 22 forms the end face of the wind box group in the pallet movement direction. The end surface member 22 is a plate-shaped member extending in the vertical direction and the width direction. The lower end of the end member 22 is fixed in close contact with the wind box 21 . Both ends of the end member 22 in the width direction are fixed in close contact with the wear bar support 12 . The plate member 15 is in contact with the outer surface of the end surface member 22, that is, the surface on the atmosphere side. A sheet member 16 is provided to cover a region extending from the dead plate 17 through the surface of the plate member 15 to the end surface member 22 . The sheet member 16 is provided outside the wind box 21, that is, on the atmosphere side. The sheet member 16 is provided over the entire width of the end member 22 . The sheet member 16 covers the sliding surfaces of the plate member 15 and the end surface member 22 and a region including the periphery thereof from the outside. The sheet member 16 may be, for example, a cloth-like member coated with a viscous paste-like substance. The plate member 15, the end surface member 22, and the sheet member 16 block the passage of air between the wind box 21 and the dead plate 17 at the end surface of the wind box group in the pallet movement direction.

In this embodiment, both ends of the dead plate 17 are fixed to wear bars. On the other hand, the dead plate 17 can also be configured to be vertically movable with respect to the wear bar.

FIG. 12 is a cross-sectional view of the girder 20b of the pallet truck 10 passing over the dead plate 17. As shown in FIG. FIG. 12 is a cross-sectional view of a plane perpendicular to the width direction. In the example shown in FIG. 12, dead plate 17 includes base material 17a and liner 17b. Thus, the dead plate 17 can be formed of multiple layers. In addition, the dead plate may be formed of a plurality of layers including other layers in addition to the base material and the liner, or may be formed of a single layer.

As shown in FIG. 12, the girder beam 20b is attached with a sealing member 3 extending below the lower surface 20g of the girder beam 20b. The seal member 3 includes a first seal member 31 and a second seal member 32 (hereinafter referred to as seal members 31 and 32 unless otherwise distinguished).

In the example shown in FIG. 12, the beam 20b has a flange 20h at the bottom. The length of the flange 20h of the girder 20b in the pallet movement direction is wider than the portion adjacent to the flange 20h of the girder 20b. The flange 20h has a protrusion 20i protruding in the pallet moving direction and a protrusion 20j protruding in the opposite direction to the pallet moving direction. The protrusions 20i, 20j are formed above the lower surface 2e of the beam 2a. The projections 20i and 20j are provided on the end face of the flange 20f in the pallet movement direction.

Sealing members 31, 32 are attached to the lower surfaces of projections 20i, 20j. The seal members 31, 32 extend inward from the lower surfaces of the projections 20i, 20j, bend downward, and extend below the lower surface 20g of the girder 20b. One ends of the sealing members 31 and 32 are attached to the protrusions 20i and 20j, and the other ends are free ends. The sealing members 31 and 32 can be plate-like sheets. The seal members 31 and 32 are attached to the girder beam 20b in a curved state. Also, the protrusions 20i, 20j and the seal members 31, 32 may be formed over the entire width direction of the girder 20b.

When the pallet truck 10 passes over the dead plate 17 , the seal members 31 and 32 come into contact with the dead plate 17 . The seal members 31 and 32 block the gap between the dead plate 17 and the beam 2a. As a result, wind leakage is further suppressed.

The seal members 31 and 32 have flexibility. That is, therefore, the sealing members 31 and 32 are elastically deformable. For example, the seal members 31 and 32 can be pushed from below by the dead plate 17 and elastically deformed such that the entire seal members 31 and 32 are retracted above the lower surface 20g of the girder 20b. As a result, when the distance T1 between the dead plate 17 and the lower surface 20g of the girder 20b becomes approximately 0 mm, the seal members 31 and 32 are retracted above the lower surface 20g of the girder 20b, and when the distance T1 is not 0 mm. , can extend downward from the lower surface 20 g to contact the dead plate 17 .

The first sealing member 31 and the second sealing member 32 extend from the beam 20b (first member) toward the dead plate 17 (second member) and further curve. The bending directions of the first sealing member 31 and the second sealing member 32 are opposite to each other. The first seal member 31 extends downward from the beam 20b and curves in the direction opposite to the pallet moving direction. The second seal member 32 extends downward from the beam 20b and curves in the pallet movement direction. Thus, two sealing members 31 and 32 curved in mutually opposite directions can be provided on the girder beam 2b of one pallet truck. As a result, both when the pallet truck 10 passes over the dead plate 17 on the ore supply side and when it passes over the dead plate 17 on the ore discharge side, due to the pressure difference between the wind box 21 and the atmosphere, The curved portion of the first sealing member 31 or the second sealing member 32 is pressed against the dead plate 17 . That is, in either case, the pressure difference can improve the ability of the sealing member to follow the dead plate.

The feed side deadplate 17 is the deadplate where the pallet truck 10 enters the upper track of the windboxes. In this case, the first seal member 31 curves from the portion in contact with the dead plate 17 and extends toward the space H where the pressure is high. is the dead plate 17 where it exits the upper track of the . In this case, the second seal member 32 is curved from the portion in contact with the dead plate 17 and extends toward the space H where the pressure is high.

In the example shown in FIG. 12, two sealing members are provided for one beam 20b. On the other hand, one sealing member may be provided for one beam 20b. For example, the protrusion 20i protruding in the pallet moving direction may be provided with a sealing member, and the protrusion 20j protruding in the opposite direction to the pallet moving direction may be provided with no sealing member or without such a protrusion 20j itself. . Conversely, even if the projection 20j projecting in the direction opposite to the pallet moving direction is provided with a sealing member, and the projection 20i projecting in the pallet moving direction is not provided with a sealing member or such a projection 20i itself is not provided. good. Also, the configuration of the seal member 3 is not limited to the example shown in FIG. As the configuration of the sealing member 3, for example, any one of the configurations shown in FIGS. 1 to 7 can be adopted.

In the example shown in FIG. 12, the sealing members 31 and 32 are provided so as to be located in the shadows of the projections 20i and 20j with respect to the flow direction of the sintering exhaust gas. This makes it difficult for dust contained in the sintering exhaust gas to collide with the sealing members 31 and 32 .

In this embodiment, a seal member 3 is provided for each of a plurality of pallet trucks 10 that move on an endless track. As a result, the wear speed of the seal member becomes slower than when the seal member is provided on the dead plate 17 . That is, the life of the seal member 3 is lengthened.

(heat treatment furnace)
Next, an example of a heat treatment furnace including a sealing device will be described. FIG. 13 is a cross-sectional view showing a configuration example of a heat treatment furnace. 14 is a side view of the portion including the opening 71A shown in FIG. 13 as viewed in the direction of arrow A. FIG. In the example shown in FIG. 13, a heat treatment furnace 71A has an opening 71A for passing a plate material 72, which is a material to be heat treated. The openings 71A include an opening 71A for putting the plate into the furnace and an opening 71A for taking it out of the furnace. The interior of the heat treatment furnace 71A is heated by a burner 72 . The gas in the heat treatment furnace 71A is exhausted from the exhaust port 73. As shown in FIG. The exhaust port may be connected to, for example, an induction fan (not shown) that induces gas in the furnace. The pressure inside the furnace is lower than the pressure outside the furnace (atmospheric pressure).

A seal member 3 is provided in the opening 71A of the heat treatment furnace 71 . The seal member 3 extends from the edge of the opening 71A, reaches the plate member 72 passing through the opening 71A, curves away from the plate member 72 from the portion in contact with the plate member 72, and extends out of the furnace, that is, toward the high pressure side. The tip of the seal member 3 is positioned outside the furnace. The seal member 3 serves as an entrance and exit seal for the heat treatment furnace 71 .

The sealing member 3 is provided on both of the two opposing edges of the opening 71A (upper edge and lower edge in the example of FIG. 13). A seal member 3 on one edge (eg, the upper edge) extends from one edge to the other edge, curves and extends into a high pressure space (eg, outside the furnace). The sealing member 3 at the other edge (eg the lower edge) extends from the other edge towards the one edge, curves and extends into the high pressure space (eg outside the furnace). A plate member 72 passing through the opening 71A is inserted between the curved portion of the seal member 3 on one edge and the curved portion of the seal member 3 on the other edge.

As the configuration of the sealing member 3, for example, any one of the configurations shown in FIGS. 1 to 7 can be adopted. A cushioning material such as felt may be attached to the curved surface of the sealing member 3 that slides on the plate member 72 . This can prevent the plate member 72 from being scratched due to the seal member 3 rubbing against the plate member 72 .

The plate material 72, which is the material to be heat-treated, may be, for example, a steel plate. When a steel plate is heated and annealed, it may be heated to, for example, around 600° C. and then cooled. A slight negative pressure is maintained in the furnace. Therefore, the combustion exhaust gas and the high-temperature atmosphere gas are operated so as not to leak from the opening 71A, which is the entrance/exit of the plate member 72, to the atmosphere side. If there is a gap in the opening 71A, oxygen-containing cool air enters. As a result, the inside of the furnace may cool and the steel plate may oxidize. Therefore, it is preferable to strengthen the sealing of the opening 71A to prevent the leaked air from entering. Steel sheets with various plate thicknesses can be heat-treated materials. However, the dimensions of the opening 71A cannot be changed whenever the size of the plate member 72 changes. Therefore, conventionally, it was necessary to adjust the position of the sealing member according to the size of the plate member 72 .

By using the sealing member 3 having the above configuration, even if the plate thickness of the plate member 72 changes, the position of the sealing member need not be adjusted as long as the change is within the allowable range. In other words, heat treatment can be performed on steel plates of various sizes without adjusting the sealing member.

(keren, painting equipment)
The configurations shown in FIGS. 13 and 14 can be applied to other than heat treatment furnaces. For example, a scraping device for sandblasting the surface of a plate material by spraying particles on the surface can be configured in the same manner as in FIGS. In this case, for example, the cleaning device has a configuration in which the heat treatment furnace 71 is replaced with a hood 71, and the burner 72 is replaced with a nozzle 72 for injecting an abrasive such as sand in the configuration shown in FIG.

Sandblasting is generally used to remove rust from the surface of a steel plate. In sandblasting, a large amount of sand is pneumatically transported and jetted through a nozzle to impinge on the steel plate surface. Sandblasting is carried out in a box-like enclosure sealed with a hood to prevent blasting sand (sand) and dust from scattering. It is preferable to prevent sand and dust from blowing out from the entrance and exit of the hood 71 through which the plate member 72 passes, that is, from the opening 71A of the hood 71 . Therefore, the inside of the hood 71 is evacuated in an amount larger than the amount of air for transporting the sand, and the inside of the hood is kept at a negative pressure. However, since the sand is particles, there are cases where the sand pops out from the gap of the opening 71A against the invading air. In order to prevent this, it is desirable to attach a sealing material.

According to this embodiment, as a sealing member for the opening 71</b>A of the hood 71 , it is possible to provide a physical sealing member that can follow changes in plate thickness and has high wear resistance. For example, even when the plate member 72 is inserted into the opening 71A of the hood 71, the sand can be prevented from being ejected from the opening 71A. Therefore, the plate member 72 can be passed through the opening 71A while continuing the sandblasting work. In addition, when the plate member 71 is not inserted between the seal member 3 on one edge and the seal member 3 on the other edge, the free length of the seal member 3 is adjusted so that the curved portions of these two seal members 3 are in contact with each other. can be set. As a result, the opening 71A can be closed when the plate 72 does not pass through the opening 72A, such as when the plate 72 is completely inside the hood 71 .

After the steel plate has been ground-treated by sandblasting, etc., the coating process begins immediately. In the case of painting, the paint is made into fine droplets with air or the like and sprayed onto the surface of the steel sheet to form a coating film. A coating device for this coating can also have a configuration similar to that shown in FIGS. In this case, the coating apparatus has a configuration in which, for example, the heat treatment furnace 71 in the configuration shown in FIG. Also in this case, as in sandblasting, the sealing member 3 can prevent fine droplets of paint floating in the air from being ejected from the opening 71A. That is, when the plate member 72 is passed through the opening 71A, no paint dust is blown out, and the painting work can be continued while preventing environmental pollution.

The example shown in FIG. 13 is an example in which the pressure inside the container is lower than the pressure outside the container. FIG. 15 is a cross-sectional view showing an example in which the pressure inside the container is higher than the pressure outside the container. In the example shown in FIG. 15, the sealing member 3 extends from the edge of the opening 71A, reaches the plate member 72 passing through the opening 71A, bends from the portion in contact with the plate member 72, leaves the plate member 72, and moves to the inside of the container 71, that is, the pressure pressure. Extends into high space. The tip of the seal member 3 is positioned in a high-pressure space.

(Continuous firing kiln)
Next, an example of a continuous firing kiln including a sealing device will be described. FIG. 16 is a cross-sectional view showing a configuration example of a firing kiln. 17 is a side view of the portion including the opening 71A shown in FIG. 16 as viewed in the direction of arrow A. FIG. The firing kiln 71 has an opening 71A through which an object to be fired passes, a burner 72 that heats the interior of the kiln, and an exhaust port 73 that discharges gas from the kiln. Also, a heat-resistant chain 84, which is a conveyor for placing and moving objects to be fired, is arranged from the outside to the inside of the kiln through the opening 71A. The heat resistant chain 84 is, for example, a ceramic chain. The kiln is operated under negative pressure.

A sealing member 3 is provided in the opening 71A of the firing kiln 71 . The sealing member 3 extends from the edge of the opening 71A, reaches the object 82 to be fired or the heat-resistant chain 83 passing through the opening 71A, and bends from the portion in contact with the object 82 to be fired or the heat-resistant chain 83 to reach the object 82 or the heat-resistant chain 83. away from the kiln and extends out into the high pressure space. The tip of the seal member 3 is positioned in a high-pressure space. The sealing member 3 serves as a seal for the entrance and exit of the firing kiln 71 .

The sealing member 3 is provided on both of the two opposing edges of the opening 71A (the upper edge and the lower edge in the example of FIG. 17) and the other two opposing edges (the left edge and the right edge in the example of FIG. 17). edge). The sealing member 3 on one edge of the two opposing sides is curved from one edge to the other edge, and extends to a high-pressure space. The other edge sealing member 3 extends from the other edge toward the one edge, curves and extends into a high pressure space (eg, outside the furnace). An object 82 to be fired and a heat-resistant chain 83 passing through the opening 71A are inserted between the curved portion of the sealing member 3 on one edge and the curved portion of the sealing member 3 on the other edge. As the configuration of the sealing member 3, for example, any one of the configurations shown in FIGS. 1 to 7 can be adopted.

The fired product may be, for example, a molded brick or the like. In a continuous firing kiln that fires molded bricks, the shaped bricks before firing are placed on a heat-resistant chain, and continuously carried into and out of a long, narrow, high-temperature firing kiln of several tens of meters. At this time, the better the sealing of the outside air at the entrance and exit of the bricks of the firing kiln, the longer the high temperature zone in the kiln. In the past, air leaked into the kiln from the entrance of the bricks of the kiln. Air leaked into the kiln, creating a zone of low temperature for several meters inside the kiln.

According to the seal member 3 of the present embodiment, the seal plate member 3 can be brought into contact with and slid around the conveyed object including the object to be fired and the heat-resistant chain passing through the opening 71A. Thereby, the temperature drop in the kiln can be reduced. As a result, the amount of fuel used can be reduced.

Although one embodiment of the present invention has been described above, the above-described embodiment is merely an example for carrying out the present invention. Therefore, the present invention is not limited to the above-described embodiment, and it is possible to modify the above-described embodiment appropriately without departing from the scope of the invention.

1: first member 2: second member 3: sealing member 31: first sealing member 32: second sealing member

Claims (7)

a first member;
a second member that moves relative to the first member while being separated from the first member;
a sealing member disposed between the first member and the second member, the sealing member being fixed to the first member and slidably contacting the second member;
The first member, the second member and the sealing member are configured to partition two spaces with different pressures,
the first member and the second member move relative to each other in a direction parallel to the sliding surface between the seal member and the second member;
The sealing member includes a curved plate, extends from the first member to reach the second member, and further curves from a portion in contact with the second member to move away from the second member to separate the two spaces. Extending toward the high-pressure space, the tip of the sealing member in the direction in which the curved plate extends is located in the high-pressure space,
The sealing member includes a first sealing member including a curved plate and a second sealing member including a curved plate ,
The first sealing member extends from the first member to reach the second member, and further curves from a portion in contact with the second member to move away from the second member so that the pressure of the two spaces is higher. extending toward the space, the tip of the first sealing member in the direction in which the curved plate extends is located in the space where the pressure is higher,
The second sealing member extends from the first member to reach the second member, and further curves from a portion in contact with the second member to move away from the second member so that the pressure between the two spaces is lower. A sealing device extending toward the space, wherein the tip of the second sealing member in the extending direction of the curved plate is located in the low pressure space. The first sealing member and the second sealing member of the sealing member are configured by stacking a plurality of curved plates, and the curved surface of one of the plurality of plates is in contact with the second member. 2. The sealing device of claim 1. 3. The sealing device according to claim 1, wherein in each of said first sealing member and said second sealing member of said sealing member, a portion in contact with said second member has a greater thickness than other portions. The first member is a container having an opening,
the second member is movable between the outside and the inside of the container through the opening;
The first sealing member extends from an edge of the opening to reach the second member passing through the opening, curves away from the second member from a portion in contact with the second member, and is configured to seal the inside and outside of the container. , the tip of the first sealing member in the direction in which the curved plate extends is located in the higher pressure side of the inside and outside of the container ,
The second sealing member extends from the edge of the opening to reach the second member passing through the opening, curves away from the second member from a portion in contact with the second member, and seals the inside and outside of the container. Among them, claims 1 to 3, wherein the tip of the second sealing member in the direction in which the curved plate extends is located in the higher pressure side of the inside and outside of the container. The sealing device according to any one of Claims 1 to 3. a first member;
a second member that moves relative to the first member while being separated from the first member;
a sealing member disposed between the first member and the second member, the sealing member being fixed to the first member and slidably contacting the second member;
The first member, the second member and the sealing member are configured to partition two spaces with different pressures,
the first member and the second member move relative to each other in a direction parallel to the sliding surface between the seal member and the second member;
The sealing member includes a curved plate, extends from the first member to reach the second member, and further curves from a portion in contact with the second member to move away from the second member to separate the two spaces. Extending toward the high-pressure space, the tip of the sealing member in the direction in which the curved plate extends is located in the high-pressure space,
The second member is a plate-shaped member extending outward from the edge of the opening on the upper surface of the box surrounding one of the two spaces with the lower pressure,
The first member is a member that constitutes the lower surface of the carriage that moves to a position that closes the opening,
the plate member is formed to extend outward from at least one of both ends of the opening in the moving direction of the carriage,
The sealing device, wherein the sealing member is in contact with the plate member when the first member moves over the second member. 6. The sealing device according to claim 5, wherein the tip of said sealing member is located above the lower surface of said first member. A sintering machine having the sealing device according to claim 5 or 6 and a plurality of pallet trucks that move on an endless track,
Each of the pallet trucks includes:
a plurality of girder beams extending in the width direction and arranged side by side in the pallet movement direction of the pallet truck;
a pair of side frames supporting both ends of the plurality of girder beams and extending in a pallet moving direction;
a plurality of great bars bridged over the upper portions of the plurality of girder beams and arranged in the width direction;
a pair of seal bars attached to the lower surfaces of the pair of side frames so as to move up and down;
a wind box group composed of a plurality of wind boxes arranged in the pallet movement direction below the pallet truck in a region where the pallet truck loaded with raw materials for sintering moves;
a pair of wear bars arranged at positions in contact with the lower surfaces of the pair of seal bars and formed to extend in the pallet movement direction;
a pair of wear bar supports that respectively support the pair of wear bars below the pallet truck;
a flexible dead plate disposed between the pair of wear bars under the pallet truck outside in the pallet movement direction from at least one of both ends of the wind box group in the pallet movement direction; , and
The sintering machine, wherein the first member is the girder, the second member is the dead plate, and the box is the wind box.

Images