JPH09264504A - Antivibration frame of refuse incineration plant - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a strong antivibration frame for a refuse incineration plant which does not abruptly reduce resistance against earthquake force by preventing stress of the incineration plant frame and the refuse incineration plant from being concentrated. SOLUTION: The antivibration frame strongly couples a rear member of a horizontal frame 13 of a boiler frame 11 and a floor support member 17 of a building located behind the boiler frame horizontally of the boiler frame. A front member of the horizontal frame and a pit side wall 21 are coupled therebetween horizontally of the boiler through a damper 22 having a damping force vector. In this case, the rear member of the horizontal frame of the boiler frame and the floor support member 17 of a building located behind the boiler frame are coupled therebetween horizontally of the boiler frame through a damper 22 having a sampling force vector.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vibration control frame for suppressing vibration of a refuse incineration plant generated during an earthquake.

[0002]

2. Description of the Related Art As shown in FIG. 19, in a refuse incinerator, a loading stage 1 for entering and leaving a garbage truck, a garbage pit 2 for injecting garbage, an incinerator 3 for burning the garbage, and a heat of exhaust gas of the garbage are used. Boiler 4, which generates steam,
Also, equipment such as an exhaust gas treatment device 5 for removing harmful components in the exhaust gas that has passed through the boiler 4 is housed in a building 6 having a reinforced concrete structure or a steel frame reinforced concrete structure.

The incinerator 3 and the boiler 4 are provided between the waste pit 2 and the exhaust gas treatment equipment 5, and the boiler 4 is installed in the incinerator 3 in order to smoothly flow the rising combustion exhaust gas.
It is provided on. Further, since there is a dust input hopper in the front part of the incinerator 3, the front-rear center of the boiler 4 is provided eccentrically rearward of the front-rear center of the incinerator 3.

As shown in FIGS. 20 and 21, the incinerator 3 is held by an incinerator frame 10 and the boiler 4 is held by a boiler frame 11. The incinerator frame 10 and the boiler frame 11 are collectively referred to as a refuse incineration plant frame. The boiler and incinerator are collectively referred to as a refuse incineration plant. In addition to the waste incineration plant, the waste incineration plant frame also holds an inspection corridor.

As described above, since the center of the boiler is eccentric to the rear of the center of the incinerator in the front-rear direction, the center of the boiler frame 11 is eccentric to the rear of the center of the incinerator frame 10 in the front-rear direction. Therefore, the boiler frame 1
The rear portion of the incineration furnace frame 10 extends rearward from the rear end of the incinerator frame 10.

A frame-shaped horizontal frame 13 is fixedly provided on the upper part of the incinerator frame 10, and the column base 11a of the boiler frame 11 is fixed on the horizontal frame 13. Leg members 14 with a base plate 15 are attached to both ends of a rear member of the horizontal frame 13. Reference numeral 16 is a floor on which an exhaust gas treatment device is installed, and 17 is a reinforced concrete structure supporting the floor 16 or a floor support member made of steel frame reinforced concrete. Reference numeral 18 denotes a support base provided so as to project forward from the floor support member 17. The base plate 15 of the leg member 14 is supported by the support base 18. As shown in FIG. 22, a plurality of bolts 19 are planted on the support base 18, while the base plate 15 is formed with a long hole 15a elongated in the front-rear direction. Then, the base plate 15 has its elongated hole 15a passed through a bolt 19 and is fastened by a nut more loosely than a predetermined torque. That is, the boiler frame 11 has its front part supported by the incinerator frame 10 via the horizontal frame 13 during normal times and earthquakes, and its rear part supported by the floor support member 17 of the building. The rear part is supported by the boiler frame 11
This is to prevent torsional vibration in which the rear part of the refuse incineration plant frame is deformed more than the front part due to the eccentricity. The elongated holes of the base plate 15 absorb the expansion due to the thermal expansion in the front-rear direction. Further, this elongated hole prevents stress from being generated in the frame member due to thermal expansion.

In addition, a high-height boiler (height example: 1
In order to suppress mutual vibrational displacement of the boiler 4 and the boiler frame 11 when a ground motion is applied to the 3.5 m) 4 from the front-rear direction or the left-right direction, as shown in FIGS. Stoppers 20 are provided at a plurality of positions between the frames 11. As shown in FIG. 23, this stopper 20 is provided with a male stopper 20a on a backstay 4a attached so as to surround the outer circumference of the boiler 4.
Female stoppers 20b and 20b are provided on the horizontal brace 11b of the boiler frame facing the backstay 4a, and the male stopper 20a is fitted into the concave portion 20c of the female stopper. Then, the male stopper 1 can prevent vibration displacement in the left-right direction and the front-rear direction of the boiler 4 caused by an earthquake motion above a certain level.
Female stoppers 20b, 20b of the boiler frame via 1b
The structure is controlled by.

As a seismic-resistant structure of a boiler frame, Japanese Patent Laid-Open No. 62-62
-66004 and JP-A-62-66005 have been published. These are related to a suspended boiler, and Japanese Patent Laid-Open No. 62-66004 discloses that a strength member of a boiler body and a strength member of a boiler frame that surrounds and suspends the boiler body are supported with slip resistance. The fixed cylinder and rod are provided so that when a large external force acts, a slip is generated between them so that the reaction force from the boiler frame is not transmitted to the boiler body. Further, Japanese Patent Laid-Open No. 62-66005 discloses that a male stopper and a female stopper are provided between a strength member of a boiler main body and a strength member of a boiler frame that surrounds and suspends the boiler main body, and the male stopper is attached to the boiler main body. The strength member is fastened via a shear bolt, and when a large external force is applied, the shear bolt is cut so that the reaction force from the boiler frame is not transmitted to the boiler body.

[0009] The suspended boiler is characterized by a large relative displacement between the boiler frame and the boiler body during an earthquake, and the main purpose of these is to prevent serious damage to the boiler body due to collision between the boiler body and the boiler frame. It is in.

However, these technologies have different support structures from those of the suspended boiler, and there is little need to apply them to a refuse incineration plant frame with a small relative displacement.

No technology has been published that improves the earthquake resistance of the refuse incineration plant frame.

[0012]

In the front-back direction, the boiler and the boiler frame have a peculiar structure in which they are overhung rearward from the incinerator frame. Therefore, in order to prevent the torsional vibration in which the rear part of the refuse incineration plant is deformed from the front part, the rear part of the horizontal frame is rigidly connected to the floor support member of the building in the left and right direction of the boiler frame in the rear part.

However, even in this state, when the seismic motion acts in the left-right direction, the front part of the horizontal frame is largely displaced in the left-right direction, and the boiler frame is twisted and deformed with the rear end of the column base height as the fulcrum. As a solution to this problem, it is conceivable to rigidly connect the front part of the horizontal frame to the front pit wall in the left-right direction of the boiler frame.However, the thermal expansion of the front part of the incinerator is large, so thermal stress may occur. And cannot be rigidly connected. If the torsional deformation becomes large, a partial excessive deformation will be forced. It is considered that stress concentrates on the members of the waste incineration plant frame and the waste incineration plant itself, and the resistance to earthquakes decreases sharply.

When a seismic motion is applied in the front-rear direction, since the rigid center and the center of gravity coincide with each other, no twisting deformation occurs, only translational deformation. However, the joining of the long holes for releasing the thermal expansion. I have no choice but to make a part. If rigidly connected, the seismic force of the refuse incineration plant will be reduced and the seismic resistance will be improved.

The present invention suppresses the above-mentioned torsional deformation in the horizontal direction of the boiler frame and translational deformation in the longitudinal direction of the boiler frame, which cannot be transmitted to the building, because the thermal expansion is released and the seismic force cannot be transmitted to the building. It is an object of the present invention to provide a seismic control frame for a refuse incineration plant that has high toughness and that prevents stress concentration in the refuse incineration plant and the waste incineration plant and does not sharply reduce the resistance to seismic forces.

[0016]

The present invention achieves the above object by the following vibration control frame.

According to a first aspect of the present invention, the rear member of the horizontal frame of the boiler frame and the floor support member of the building behind the boiler frame are rigidly connected in the horizontal direction of the boiler frame, and the front member of the horizontal frame and the pit side wall are connected. This is a seismic control frame of a refuse incineration plant in which the space is connected via a damper having a damping force vector in the left-right direction of the boiler frame.

According to a second aspect of the present invention, the rear member of the horizontal frame of the boiler frame and the floor support member of the building behind the boiler frame are rigidly connected in the horizontal direction of the boiler frame, and either one of the left and right members of the horizontal frame is connected. A seismic control frame for a refuse incineration plant in which the building components are connected to each other via a damper having a damping force vector in the left-right direction of the boiler frame.

A third aspect of the present invention is a waste in which a rear member of a horizontal frame of a boiler frame and a floor support member of a building behind the boiler frame are connected via a damper having a damping force vector in the horizontal direction of the boiler frame. It is the seismic control frame of the incineration plant.

In a fourth aspect of the present invention, the space between the rear member of the horizontal frame of the boiler frame and the floor support member of the building behind the boiler frame is on the horizontal center line in the horizontal direction of the horizontal frame and in the front-back direction of the boiler frame. This is a seismic control frame of a refuse incineration plant that is connected by a damper having a damping force vector.

According to a fifth aspect of the invention, the rear member of the horizontal frame of the boiler frame and the floor support member of the building behind the boiler frame are rigidly connected in the left-right direction of the boiler frame, and the front member of the horizontal frame and the pit sidewall are connected. Between them via a damper having a damping force vector in the horizontal direction of the boiler frame, and between the rear member of the horizontal frame and the floor support member at the rear of the boiler frame on the horizontal center line of the horizontal frame. It is a seismic control frame of a refuse incineration plant that is connected with a damper having a damping force vector in the front-back direction of the boiler frame.

According to a sixth aspect of the present invention, the rear member of the horizontal frame of the boiler frame and the floor support member of the building behind the boiler frame are rigidly connected in the horizontal direction of the boiler frame, and either one of the left and right members of the horizontal frame is connected. The building components are connected via a damper having a damping force vector in the horizontal direction of the boiler frame, and the horizontal frame is connected between the rear member of the horizontal frame and the floor support member of the building behind the boiler frame. Is a seismic control frame of a refuse incineration plant, which is located on the horizontal center line in the left-right direction and is connected by a damper having a damping force vector in the front-back direction of the boiler frame.

In a seventh aspect of the invention, a rear member of a horizontal frame of the boiler frame and a floor support member of a building behind the boiler frame are connected via a damper having a damping force vector in the horizontal direction of the boiler frame, Further, a refuse incineration plant in which the rear member of the horizontal frame and the floor support member at the rear of the boiler frame are on the horizontal center line in the horizontal direction of the horizontal frame and are connected by a damper having a damping force vector in the front-back direction of the boiler frame. It is a seismic control frame.

[Operation] First invention: When a seismic motion is applied in the left-right direction, the damper suppresses the vibration displacement in the left-right direction of the front portion of the horizontal frame. The large twist deformation can be suppressed to be small.

Second invention: When a damper cannot be provided between the horizontal frame and the pit wall at a dust entrance or the like, and when a horizontal seismic motion is applied, the damper is largely deformed in the horizontal frame. Since the vibration displacement in the left-right direction is suppressed, large torsional deformation with the rear end of the column base height of the boiler frame as a fulcrum can be suppressed to a small value.

Third invention: Since the rear part of the horizontal frame is connected to the floor support member by a damper without being rigidly connected, when the seismic motion acts in the left-right direction, the rear part of the front part with the rear end of the horizontal frame as a fulcrum is used. Since large bending deformation is suppressed, large torsional deformation with the rear end of the column base height of the boiler frame as a fulcrum becomes small.

Fourth invention: Since the rear end of the horizontal frame and the floor support member are connected by a damper on the center line of the horizontal width of the horizontal frame, stress due to thermal expansion when a seismic motion is applied in the front-rear direction Since seismic force can be transmitted to the building without generating waste in the refuse incineration plant frame, the displacement of the upper part of the boiler frame becomes small.

Fifth invention: Since the configurations of the first invention and the fourth invention are combined, when the earthquake motion acts from the left and right directions, the torsional deformation of the boiler frame is suppressed to a small level, and when the earthquake motion acts from the front and rear directions. , The displacement of the upper part of the boiler frame can be kept small.

Sixth invention: Since the second invention and the fourth invention are combined, when the earthquake motion acts from the left and right directions,
The torsional deformation of the boiler frame can be suppressed to a small level, and the displacement of the upper part of the boiler frame can be suppressed to a small level when the earthquake motion acts from the front-back direction.

Seventh invention: Since the configurations of the third invention and the fourth invention are combined, when the earthquake motion acts from the left and right directions, the torsional deformation of the boiler frame is suppressed to a small extent, and when the earthquake motion acts from the front and rear directions. , The displacement of the upper part of the boiler frame can be kept small.

[0031]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. "First Embodiment" FIG. 1 is a side view of the first embodiment of the present invention, FIG. 2 is a view taken along the line CC of FIG. 1, and FIG. 3 is a view of the damper mounting portion of FIG. It is an enlarged plan view. 3 is a refuse incinerator, 4 is a boiler installed above the refuse incinerator, 1
Reference numeral 0 is an incinerator frame structure that surrounds and holds the refuse incinerator 3, and 11 is a boiler frame structure that surrounds and holds the boiler 4. The incinerator frame 10 is formed of H-shaped steel, a column member using a steel pipe, a horizontal brace, a diagonal brace, and a wall member.
The boiler frame 11 is a column member using H-section steel, steel pipe, etc.
It is composed of horizontal braces and diagonal braces.
In the front-rear direction, the center of the boiler 4 in the front-rear direction is eccentric to the rear of the center of the incinerator 3 in the front-rear direction. For this reason,
In the front-rear direction, the rear portion of the boiler frame 11 projects rearward from the rear end of the incinerator frame 10. In order to support the boiler frame 11 which projects to the rear in this way, a frame-shaped horizontal frame 13 is provided on the upper part of the incinerator frame 10 and its rear part projects rearward from the rear end of the incinerator frame 10. The column base 11a of the boiler frame 11 is fixed on the horizontal frame 13. This horizontal frame 13
Receives the weight of the boiler body and the boiler frame 11.
Then, leg members 14, 14 to which base plates 15 are attached are provided on both lower surfaces of the rear portion of the horizontal frame 13, and the leg members 14, 14 are formed by projecting forward from a floor support member 17 made of steel-framed reinforced concrete in the rear. It is placed on the tables 18 and 18 and bolted. The method of fastening the base plate 15 of the leg member and the support base 18 is the same as the content described with reference to FIG. That is, the boiler frame 11 has its front portion supported by the incinerator frame 10 via the horizontal frame 13 and its rear portion supported by the floor support member 17.
Further, the thermal expansion and displacement of the boiler frame 11 and the horizontal frame 13 in the front-rear direction can be absorbed.

A plurality of stoppers are provided between the boiler 4 and the boiler frame 11 in order to suppress vibration displacement of the boiler 4 when an earthquake motion is applied to the boiler 4 from the left and right directions. The stopper is “conventional technology” and is shown in FIGS.
Since the structure is the same as that described with reference to FIG. 23, description thereof will be omitted.

Reference numeral 21 denotes a side wall of the dust pit 2, which is made of steel frame reinforced concrete. In this embodiment, as shown in FIGS. 1 and 2, the front member of the horizontal frame 13 supporting the boiler frame 11 and the waste pit side wall 21.
The two are connected via a damper 22 provided so as to have a damping force vector in the left-right direction. This damper 2
The mounting structure of No. 2 will be described with reference to FIG.

The horizontal frame 13 has its front member 13a.
A strong mounting base 23b is mounted on the front surface of the center line 30 in the left-right direction. Further, a strong mounting base 23a is mounted at a position separated by a certain distance in the right direction at the mounting height of the mounting base 23b on the rear surface of the side wall 21 of the dust pit facing the horizontal frame 13. Pins 24b, 24 are provided on the upper surfaces of the two mounts 23b, 23a.
a are attached in parallel to the front surface of the horizontal frame 13. Then, the damper 22 has a pin 2 at one end.
The other end of the pin 4 is loosely fitted to the pin 24a so as to be displaceable in the vertical direction. When both ends of the damper 22 can be rotated with respect to the pins 24b and 24a, seismic motion acts so that the dust pit side wall 21 and the front member 13a of the horizontal frame are not parallel to each other, or the distance between the two changes. However, no excessive force is applied to the damper 22. Damper 2 when the seismic motion acts to the left and right
When 2 is an oil damper, a lateral force of the front member 13a of the horizontal frame and the dust pit side wall 21 is generated according to the relative speed in the left-right direction to suppress the horizontal displacement of the boiler frame 11.

As the damper 22, a speed-dependent oil damper or a seismic isolation rubber is used instead of a displacement-dependent one such as a hysteresis damper in steel.

Although FIG. 3 shows an example in which the mounting base 23b is mounted on the horizontal center line 30 of the front member 13a of the horizontal frame, it may be mounted at any position of the front member 13a. Good. Of course, in this case, the waste pit sidewall 21
The mounting position of the side mounting base 23b is changed according to the position of the mounting base 23b.

[Second Embodiment] As shown in FIG.
The rear member 13b of the horizontal frame 13 and the floor support member 17 of the building behind the boiler frame 11 are rigidly connected in the left-right direction of the boiler frame, and between the right member 13c of the horizontal frame and the building component 35 such as the floor support member. Are connected by a damper 22 having a damping force vector in the left-right direction of the boiler frame.

Since the mounting structure of the damper 22 is similar to that of the first embodiment, the description thereof will be omitted.

[Third Embodiment] FIG. 5 is a side view of the third embodiment of the present invention, FIG. 6 is a view taken along the line D--D of FIG. 5, and FIG. 7 is a damper of FIG. It is an enlarged plan view of a mounting portion.

In this embodiment, unlike the first embodiment, the base plate 15 of the leg member of the horizontal frame 13 is mounted on the support base 18 and is not bolted. That is, the base plate 15 is placed in a state of being movable in the left-right direction and the front-back direction on the support base. The description of the other reference numerals is the same as that of the first embodiment, so the description thereof is omitted.

In this embodiment, as shown in FIGS. 5 and 6, a horizontal direction is provided between the rear surface of the rear member 13b of the horizontal frame 13 supporting the boiler frame 11 and the front surface of the floor supporting member 17. Are connected via a damper 22 provided so as to have a damping force vector. The mounting method of this damper will be described with reference to FIG.

On the horizontal frame 13, the rear member 13b
A strong mount 23b is mounted on the rear surface of the center line 30 in the left-right direction. Further, a strong mounting base 23a is mounted on the front surface of the floor supporting member 17 facing the horizontal frame 13 at a mounting height of the mounting base 23b and at a position separated by a certain distance in the left direction. Pins 24b and 24a are provided on the upper surfaces of the two mounts 23b and 23a.
Are attached in parallel to the rear surface of the horizontal frame 13. The damper 22 has a pin 24 at one end.
The other end of the pin b is loosely fitted to the pin 24a so that it can be displaced vertically in a fixed manner. Since both ends of the damper 22 can be rotated with respect to the pins 24b and 24a, even if the floor support member 17 and the rear member 13b of the horizontal frame are no longer parallel to each other or the distance between them changes due to seismic motion. The damper 22 is not subjected to excessive force. When the earthquake motion acts to the left and right, the damper 22
However, a lateral force of the rear member 13b of the horizontal frame and the floor support member 17 is generated according to the relative speed in the left-right direction, and the horizontal displacement of the boiler frame 11 is suppressed to a small level.

Although FIG. 7 shows an example in which the mount 23b is mounted on the horizontal center line 30 of the rear member 13b of the horizontal frame, it may be mounted at any position on the rear member 13a.

[Fourth Embodiment] FIG. 8 is a side view of the fourth embodiment of the present invention, FIG. 9 is a view taken along the line EE of FIG. 8, and FIG. 10 is a damper of FIG. It is an enlarged plan view of a mounting portion.

In this embodiment, the base plate 15 of the leg member of the horizontal frame 13 is fastened to the elongated hole of the base plate 15 through the bolts planted in the support 18 as in the first embodiment. ing. The description of the other reference numerals is the same as that of the first embodiment, so the description thereof is omitted.

In this embodiment, as shown in FIGS. 8 and 9, the space between the rear surface of the rear member 13b of the horizontal frame 13 supporting the boiler frame 11 and the front surface of the floor supporting member 17 is set in the front-rear direction. Are connected via a damper 22 provided so as to have a damping force vector. The mounting method of this damper will be described with reference to FIG.

On the horizontal frame 13, the rear member 13b
A strong mount 23b is mounted on the rear surface of the center line 30 in the left-right direction. Further, a firm mounting base 23a is mounted on the front surface of the floor support member 17 facing the horizontal frame 13, and the mounting position is an intersection with the extension line of the horizontal width center line 30 of the horizontal frame 13. Pins 24 are provided on the upper surfaces of the two mounts 23b and 23a.
b and 24a are attached respectively, and these pins 24b and 24a are on a vertical plane including the horizontal width center line 30 of the horizontal frame 13. And the damper 22
However, one end is loosely fitted to the pin 24b and the other end is fitted to the pin 24a so as to be displaceable in the vertical direction. Since both ends of the damper 22 can be pivoted with respect to the pins 24b and 24a, seismic motion acts and the floor support member 17 and the rear member 13b of the horizontal frame are not parallel to each other.
Even if the distance between the two changes, the damper 22 is not unduly applied. When the earthquake motion acts in the front-rear direction, the damper 22 generates a drag force according to the front-rear relative speed of the rear member 13b of the horizontal frame and the floor support member 17 to suppress the displacement of the boiler frame 11 in the front-rear direction.

[Fifth Embodiment] FIG. 11 is a side view of the fifth embodiment of the present invention, and FIG. 12 is a sectional view taken along line F-F of FIG.
FIG. 13 is an enlarged plan view of the damper mounting portion of FIG.

This embodiment is a combination of the first embodiment and the fourth embodiment. In this embodiment, the base plate 15 of the leg member of the horizontal frame 13 is fastened to the elongated hole of the base plate 15 through the bolts planted in the support base 18, as in the first embodiment. The description of the other reference numerals is the same as that of the first embodiment, so the description thereof is omitted.

In this embodiment, as shown in FIGS. 11 and 12, between the front member of the horizontal frame 13 supporting the boiler frame 11 and the waste pit side wall 21 on the front side of the horizontal frame 13. , A rear member 13 of the horizontal frame 13 that supports the boiler frame 11 on the rear side of the horizontal frame 13 by connecting them via a damper 22 provided so as to have a damping force vector in the left-right direction.
The rear surface of b and the front surface of the floor support member 17 are connected via a damper 22 provided on the horizontal width center line of the horizontal frame and having a damping force vector in the front-rear direction.

The mounting method of the damper 22 for connecting the front member 13a of the horizontal frame 13 and the dust pit side wall 21 is the same as that described in the first embodiment with reference to FIG. 13b rear surface and floor support member 1
The mounting method of the damper 22 that connects the front surfaces of 7 is as follows.
Since this is the same as the description of FIG. 10 of the fourth embodiment, the description based on FIG. 13 is omitted.

When the earthquake motion acts in the left-right direction, the damper 22 connecting between the front member 13a of the horizontal frame 13 and the side wall 21 of the dust pit has the front member 1 of the horizontal frame.
3a and a drag pit side wall 21 generate | occur | produce a drag force according to the left-right direction relative speed, and suppress the left-right direction displacement of the front part of the boiler frame 11. Further, when the earthquake motion acts in the front-rear direction, the damper 22 that connects the rear surface of the rear member 13b of the horizontal frame 13 and the front surface of the floor support member 17 has the front-rear direction of the rear member 13b of the horizontal frame and the floor support member 17. A drag force corresponding to the relative speed is generated to suppress the displacement of the boiler frame 11 in the front-rear direction to be small.

[Sixth Embodiment] This embodiment is
This is a combination of the second embodiment and the fourth embodiment. As shown in FIG. 14, the rear member 13b of the horizontal frame 13 at the column base height of the boiler frame 11 and the floor support member 17 of the building behind the boiler frame are rigidly connected in the left-right direction of the boiler frame, and the right member of the horizontal frame is connected. 13c and the building component 35 are connected via a damper 22a having a damping force vector in the left-right direction of the boiler frame, and further, the rear member 13b of the horizontal frame and the floor support member 17 of the building behind the boiler frame. The two are connected by a damper 22b which is on the horizontal center line of the horizontal frame and has a damping force vector in the front-back direction of the boiler frame.

The mounting structure of the damper is similar to the structures of the first and fourth embodiments, and the description thereof will be omitted.

"Seventh Embodiment" FIG. 15 is a side view of the seventh embodiment of the present invention, and FIG. 16 is a GG line in FIG.
FIG. 17 is an enlarged plan view of the damper mounting portion of FIG.

This embodiment is the same as the third embodiment and the fourth embodiment.
It is a combination of the above-mentioned embodiments. In this embodiment, unlike the first embodiment, the base plate 15 of the leg member of the horizontal frame 13 is mounted on the support base 18 and is not bolted. That is, the base plate 15 is placed in a state of being movable in the left-right direction and the front-back direction on the support base. Since the other reference numerals are the same as those in the first embodiment, the description will be omitted.

In this embodiment, as shown in FIGS. 15 and 16, the rear surface of the rear member 13b of the horizontal frame 13 supporting the boiler frame 11 and the floor supporting member 1 are used.
The front surfaces of 7 are connected via a damper 22a provided so as to have a damping force vector in the left-right direction,
A damper 22 provided on the horizontal width center line of the horizontal frame and having a damping force vector in the front-rear direction.
b.

A method of attaching the dampers 22a and 22b will be described with reference to FIG. The mounting base 2 is provided above the center of the rear surface of the rear member 13b of the horizontal frame in the lateral direction.
3c is attached, and a mount 23b is attached below. On the other hand, on the front surface of the floor supporting member 17, a mounting base 23d is mounted at a position a certain distance leftward from the horizontal center line 30 of the horizontal frame at the same height as the mounting base 23c. . Further, on the front surface of the floor support member 17, a mounting base 23a is mounted on the extension of the horizontal center line 30 in the horizontal direction of the horizontal frame. Mounting base 23
Pins 24c and 24d are mounted on lines parallel to the rear member 13b of the horizontal frame on c and 23d, respectively. The damper 22a has a pin 24 at one end.
The other end is loosely fitted and attached to the pin 24d. The damper 22b is attached by loosely fitting one end to the pin 24a and the other end to the pin 24b. Since both ends of the damper 22a and the damper 22b can rotate with respect to the respective pins, seismic motion acts so that the floor support member 17 and the rear member 13b of the horizontal frame are not parallel to each other, or the distance between the two changes. Damper 22
Unnecessary force is not applied to a and the damper 22b. When the earthquake motion acts to the left and right, the damper 22a
However, a lateral force of the rear member 13b of the horizontal frame and the floor support member 17 is generated according to the relative speed in the left-right direction, and the horizontal displacement of the boiler frame 11 is suppressed to a small level. When the earthquake motion acts in the front-rear direction, the damper 22b generates a drag force according to the front-rear relative speed of the rear member 13b of the horizontal frame and the floor support member 17 to suppress the displacement of the boiler frame 11 in the front-rear direction.

FIG. 18 shows another example in which one damper is provided between the rear member of the horizontal frame and the floor supporting member to suppress the displacement of the boiler frame in the left-right direction and the front-back direction. In the figure, the rear member 13 of the horizontal frame
A mounting base 23b is mounted at the center of the width of the rear surface in the left-right direction. Further, the mounting base 23a is mounted on the front surface of the floor support member 13 at the same height as the mounting height of the mounting base 23b and at a position left a certain distance to the left from the center line 30 of the rear member 13b. The pin 24b is mounted on the mounting base 23b, and the pin 24a is mounted on the mounting base 23a. The damper 22 has one end attached to the pin 24b and the other end loosely fitted to the pin 24a. The damper 22 is inclined with respect to the center line 30 of the rear member of the horizontal frame. This inclination angle is 30 ° ~
60 ° is preferred.

Since both ends of the damper 22 can be rotated with respect to the pin 24b and the pin 24a, seismic motion acts so that the floor support member 17 and the rear member 13b of the horizontal frame are no longer parallel to each other, or the distance between them is small. Even if it changes
No excessive force is applied to the damper 22. Since the damper 22 is attached so as to be inclined with respect to the center line 30 of the rear member of the horizontal frame, the drag of the damper 22 has a component force in the left-right direction and the front-back direction. Therefore, when the earthquake motion acts in the left-right direction, a left-right component force of the reaction force is generated, and the left-right displacement of the boiler frame 11 is suppressed to be small. Further, when the earthquake motion acts in the front-rear direction, a front-rear component force of the drag force is generated, and the lateral displacement of the boiler frame 11 is suppressed to be small.

[0061]

According to the first invention, the second invention and the third invention, the torsional deformation with the rear end of the column base height of the boiler frame at the time of an earthquake as a fulcrum is suppressed to a small extent. It is possible to obtain a structure having high toughness that prevents excessive deformation and does not drastically reduce the earthquake resistance without stress being concentrated on the members of the refuse incineration plant frame and the refuse incinerator plant body.

According to the fourth aspect of the invention, the displacement of the boiler frame in the front-rear direction at the time of an earthquake can be suppressed to be small.

According to the fifth invention, the sixth invention and the seventh invention, the torsional deformation with the rear end of the column base height of the boiler frame as a fulcrum at the time of earthquake is suppressed to a small extent, and the boiler at the time of earthquake is also suppressed. It is possible to suppress the displacement in the front-rear direction of the frame to be small.

[Brief description of drawings]

FIG. 1 is a side view of a first embodiment of the present invention.

FIG. 2 is a view taken in the direction of arrows CC in FIG. 1;

FIG. 3 is an enlarged plan view of a damper mounting portion of FIG.

FIG. 4 is a plan view of a second embodiment of the present invention.

FIG. 5 is a side view of the third embodiment of the present invention.

FIG. 6 is a view as viewed in the direction of the arrow DD in FIG. 5;

FIG. 7 is an enlarged plan view of the damper mounting portion of FIG.

FIG. 8 is a side view of the fourth embodiment of the present invention.

9 is a view as seen from the arrow EE of FIG.

FIG. 10 is an enlarged plan view of the damper attachment portion of FIG.

FIG. 11 is a side view of the fifth embodiment of the present invention.

FIG. 12 is a view as viewed in the direction of arrows FF in FIG. 11;

13 is an enlarged plan view of the damper mounting portion of FIG.

FIG. 14 is a plan view of a sixth embodiment of the present invention.

FIG. 15 is a side view of the seventh embodiment of the present invention.

16 is a GG plan view of FIG. 15. FIG.

FIG. 17 is an enlarged plan view of the damper attachment portion of FIG.

FIG. 18 is a plan view of a damper mounting portion which is a modified example of FIG.

FIG. 19 is a side view of the refuse incineration facility.

FIG. 20 is a side view of a conventional refuse incineration plant frame.

FIG. 21 is a plan view of a conventional refuse incineration plant frame.

22 is an enlarged plan view of an A part of FIG. 20. FIG.

FIG. 23 is an enlarged plan view of a B part in FIG. 21.

[Explanation of symbols]

 3 Incinerator 4 Boiler 10 Incinerator frame structure 11 Boiler frame structure 13 Horizontal frame 13a Front member 13b Rear member 13c Right member 14 Leg member 15 Base plate 16 Floor 17 Floor support member 18 Support stand 21 Garbage pit side wall 22, 22a, 22b Damper 23a , 23b, 23c, 23d Mounting base 24a. 24b, 24c, 24d Pin 30 Horizontal center line of horizontal frame

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Junichi Murata 1-2-1, Marunouchi, Chiyoda-ku, Tokyo Nihon Kokan Co., Ltd. (72) Inventor Michio Nagaseki 1-2-1, Marunouchi, Chiyoda-ku, Tokyo Nippon Steel Tube Co., Ltd. (72) Inventor Masaaki Nishino 1-2-2 Marunouchi, Chiyoda-ku, Tokyo Nihon Steel Tube Co., Ltd.

Claims (7)

[Claims] 1. A rear member of a horizontal frame of a boiler frame and a floor support member of a building behind the boiler frame are rigidly connected in the left-right direction of the boiler frame, and a front member of the horizontal frame and a pit side wall are connected to the boiler. A seismic control frame for a refuse incineration plant, characterized in that it is connected via a damper having a damping force vector to the left and right of the frame. 2. A rear member of a horizontal frame of the boiler frame and a floor support member of a building behind the boiler frame are rigidly connected in the left-right direction of the boiler frame, and one of the left and right members of the horizontal frame and a building component member. A vibration control frame for a refuse incineration plant, characterized in that the two are connected via a damper having a damping force vector in the left-right direction of the boiler frame. 3. A horizontal frame rear member of the boiler frame and a floor support member of a building behind the boiler frame are connected via a damper having a damping force vector in the left-right direction of the boiler frame. A seismic control structure for a refuse incineration plant. 4. A damper having a damping force vector on a horizontal width center line of a horizontal frame between a rear member of the boiler frame and a floor support member of a building behind the boiler frame, and having a damping force vector in the front-back direction of the boiler frame. A seismic control structure for a refuse incineration plant characterized by being connected. 5. The rear member of the horizontal frame of the boiler frame and the floor support member of the building behind the boiler frame are rigidly connected in the left-right direction of the boiler frame, and the front member of the horizontal frame and the pit side wall are connected to the boiler. The frame is connected via a damper having a damping force vector in the left-right direction, and further, between the rear member of the horizontal frame and the floor support member behind the boiler frame is on the horizontal width center line of the horizontal frame, and the boiler is A seismic control frame for a refuse incineration plant, characterized in that it is connected with a damper having a damping force vector in the longitudinal direction of the frame. 6. The rear member of the horizontal frame of the boiler frame and the floor support member of the building behind the boiler frame are rigidly connected in the left-right direction of the boiler frame, and one of the left and right members of the horizontal frame and the building component are connected. Are connected via a damper having a damping force vector in the horizontal direction of the boiler frame, and the horizontal width of the horizontal frame between the rear member of the horizontal frame and the floor support member of the building behind the boiler frame. A seismic control frame for a refuse incineration plant, which is located on the center line and is connected by a damper having a damping force vector in the longitudinal direction of the boiler frame. 7. A horizontal member of a horizontal frame of the boiler frame and a floor support member of a building behind the boiler frame are connected via a damper having a damping force vector in the horizontal direction of the boiler frame, and the horizontal frame is further connected. The incineration of waste is characterized in that the rear member and the floor support member at the rear of the boiler frame are connected by a damper located on the horizontal width center line of the horizontal frame and having a damping force vector in the front-back direction of the boiler frame. Damping frame of the plant.