KR20110094104A - Blast furnace installation, method for improving earthquake resistance of a blast furnace installation, and linking vibration control apparatus - Google Patents

Abstract

The blast furnace installation includes a blast furnace body, a furnace body frame surrounding the blast furnace body, and a connection vibration suppression device which is installed at a position of 1/2 or more of the height of the blast furnace body and connects the blast furnace body and the furnace body frame. do.

Description

BLAST FURNACE INSTALLATION, METHOD FOR IMPROVING EARTHQUAKE RESISTANCE OF A BLAST FURNACE INSTALLATION, AND LINKING VIBRATION CONTROL APPARATUS}

The present invention relates to a blast furnace facility that has improved seismic performance, a method for improving seismic performance of a blast furnace facility, and a connection vibration suppression device.

This application claims priority based on Japanese Patent Application No. 2009-014903 for which it applied to Japan on January 27, 2009, and uses the content here.

The blast furnace installation of a steelworks has a structure in which the furnace frame for supporting raw material input facilities etc. is arrange | positioned around the blast furnace main body. In the conventional blast furnace installation, the seismic performance of the whole blast furnace installation was improved by firmly coupling a furnace body frame to the blast furnace main body. However, since the height of the furnace frame is about twice the height of the blast furnace body, there is a problem that the response (amplitude) to the earthquake in the upper part of the furnace frame is particularly excessive.

Therefore, in the blast furnace installation in the present steelworks, the structure which does not combine a blast furnace main body and a furnace frame, what is called a free stand type is taken. In the free stand type, in order to improve the seismic performance of a furnace frame, reinforcement construction which raises rigidity of the furnace frame itself is performed. However, since the structural member of a furnace body frame is expanded and each existing member needs to be reinforced, the weight of a furnace body frame will increase significantly compared with the past. However, there is a limit to the load that can be supported by the existing blast furnace installation bases (the foundation of the blast furnace body and the furnace frame). Therefore, seismic construction that leads to a significant increase in the weight of the furnace frame is difficult.

On the other hand, as a seismic performance improvement technique, Patent Literature 1 discloses a structure in which structures having different intrinsic cycles are connected by a connection vibration suppression mechanism. In addition, Patent Document 2 discloses a damping furniture for an incineration plant using a damper.

Japanese Patent Application Publication No. 2002-266517 Japanese Patent No. 3277803

However, the seismic performance improvement techniques disclosed in Patent Documents 1 and 2 do not all target high structures in which blast furnaces and furniture are integrated, such as blast furnace equipment. Moreover, the structure described in patent document 1 is not suitable for the blast furnace installation which produces heat deformation at the time of operation, since consideration regarding the heat deformation of a structure is not made. Moreover, although the vibration damping structure of patent document 2 improves the seismic performance with respect to the earthquake motion (earthquake input) of a horizontal direction (front-back, left-right direction), it cannot exhibit the damping effect efficiently about the up-down earthquake motion.

Therefore, an object of the present invention is to provide a connection vibration isolator which exhibits an effective vibration suppression effect against seismic input from all directions in a blast furnace installation of a steel mill. Moreover, an object of this invention is to provide the blast furnace installation which can cope with thermal deformation and has an efficient seismic performance by devising the mounting method of this connection vibration suppression apparatus.

(1) A blast furnace installation, a blast furnace body, a furnace body frame surrounding the blast furnace body, and a connection vibration suppression device which is installed at a position of 1/2 or more of the height of the blast furnace body and connects the blast furnace body and the furnace body frame. It includes.

(2) In the blast furnace installation described in (1), the connection vibration isolator includes a blast furnace mounting portion attached to the blast furnace body, a furnace frame mounting portion mounted on the furnace frame, and between the blast furnace mounting portion and the furnace frame mounting portion. It may comprise a stretchable damping mechanism connected, and may be attached to the blast furnace body so that the stretching direction of the damping mechanism includes the circumferential direction of the blast furnace body.

(3) In the blast furnace installation described in (1), the connection vibration isolator includes a blast furnace mounting portion attached to the blast furnace body, a furnace frame mounting portion attached to the furnace frame, and the blast furnace mounting portion and the furnace frame mounting portion. It may comprise a stretchable damping mechanism connected, and may be attached to the blast furnace body so that the stretching direction of the damping mechanism includes the radial direction of the blast furnace body.

(4) In the blast furnace installation described in the above (2) or (3), the blast furnace mounting portion may be mounted so that the vibration suppression mechanism is movable in the vertical direction.

(5) A method of improving the seismic performance of a blast furnace installation including a blast furnace body and a furnace frame surrounding the blast furnace body, wherein a connection vibration suppression device connecting the blast furnace body and the furnace frame is 1/2 of the height of the blast furnace body. Earthquake-resistant performance improvement method characterized by the above-mentioned installation.

(6) In the seismic performance improving method described in (5) above, the connection vibration isolator includes a blast furnace mounting portion attached to the blast furnace body, a furnace frame mounting portion mounted on the furnace frame, the blast furnace mounting portion and the furnace frame mounting portion. It may include a stretchable vibration damping mechanism connected between, and may be attached to the blast furnace body so that the stretching direction of the vibration damping mechanism includes the circumferential direction of the blast furnace body.

(7) In the seismic performance improving method described in (5), the connection vibration isolator includes a blast furnace mounting portion attached to the blast furnace body, a furnace body frame mounting portion mounted on the furnace frame, the blast furnace mounting portion and the furnace frame mounting portion. It may include a stretchable vibration damping mechanism connected between, and may be attached to the blast furnace body so that the stretching direction of the vibration damping mechanism includes the radial direction of the blast furnace body.

(8) A connection vibration suppression apparatus, comprising: a blast furnace mounting portion mounted on the blast furnace body, a furnace frame mounting portion mounted on the furnace frame supporting the blast furnace body, and an elastic vibration suppression mechanism connected between the blast furnace mounting portion and the furnace frame mounting portion. Include.

According to the present invention, it is possible to provide a blast furnace facility capable of coping with heat deformation and having an efficient seismic performance, and a connection vibration suppression device that exhibits an effective vibration suppression effect against seismic input from all directions in the blast furnace facility. The seismic performance of equipment is improved.

1 is a schematic side view of a blast furnace installation 1 according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view of the blast furnace installation 1 of FIG. 1 cut at plane xx.
3A is a schematic diagram of the connection vibration suppression apparatus 20 according to one embodiment of the present invention.
3B is a perspective view of the connection vibration suppression apparatus 20 according to the embodiment of the present invention attached to the blast furnace body 11.
3C is a side view of the blast furnace mounting portion 21 of the connection vibration suppression apparatus 20 according to the embodiment of the present invention mounted on the blast furnace body 11.
3D is a side view of the furnace frame mounting portion 22 of the connection vibration suppression device 20 according to the embodiment of the present invention mounted on the furnace frame 12.
4A is a schematic diagram of a connection vibration suppression apparatus 20 according to one embodiment of the present invention.
4B is a perspective view of the connection vibration suppression apparatus 20 according to the embodiment of the present invention when the ball joint 45 is used.
5 is an explanatory diagram illustrating an arrangement example of the connection vibration suppression apparatus 20.
FIG. 6: A is a perspective view of the connection damping apparatus 20 which concerns on one Embodiment of this invention attached between the blast furnace main body 11 and the furnace frame 12, as shown in FIG.
6B is a perspective view of the connection vibration suppression apparatus 20 according to one embodiment of the present invention when a ball joint is used as the connecting member.
7 is an explanatory diagram showing an arrangement example of the connection vibration suppression apparatus 20.
8 is a schematic view of the blast furnace installation 1 showing the position where the connection vibration suppression apparatus 20 is installed.
It is a figure which shows the analysis result of an Example.
10 is a schematic diagram showing a bar graph of an assumed value of a load applied to the blast furnace base 10 in the case of an earthquake, when the blast furnace installation 1 of the phenomenon is repaired.

EMBODIMENT OF THE INVENTION Hereinafter, an example of embodiment of this invention is described with reference to drawings. In addition, in this specification and drawing, duplication description is abbreviate | omitted by attaching | subjecting the same code | symbol about the component which has substantially the same functional structure.

1 is a schematic side view of a blast furnace installation 1 according to an embodiment of the present invention. The blast furnace installation 1 comprises the substantially cylindrical blast furnace main body 11 installed in the upper part of the installation base 10, the furnace body frame 12 surrounding the blast furnace main body 11, and the connection damping apparatus 20. Equipped. The furnace body frame 12 is assembled higher than the blast furnace main body 11 in order to support the raw material input equipment etc. for supplying a raw material to the blast furnace main body 11. Moreover, the furnace frame 12 is comprised from the furnace frame main body 12a and the floor beam 12b. This floor beam 12b supports a working floor (not shown), and is installed in plural heights so as to surround the blast furnace main body 11.

In the gap formed between the blast furnace body 11 and the floor beam 12b at a position (height) of 1/2 or more of the height of the blast furnace body 11, the blast furnace body 11 and the furnace body frame 12 (floor beam 12b ) Is provided with a plurality of connection vibration suppression apparatuses 20. FIG. 2 is a cross-sectional view of the blast furnace installation 1 of FIG. 1 cut at the x-x plane. The connection vibration suppression apparatus 20 is provided in the clearance gap between the outer peripheral surface of the blast furnace main body 11, and the inner surface of the bottom beam 12b. In one Embodiment of this invention, ten connection vibration damping apparatuses 20 are used so that the vibration damping mechanism 23 mentioned later is arrange | positioned along the outer periphery of the blast furnace main body 11 in the circumferential shape. In addition, in the example shown in FIG. 2, although the connection vibration suppression apparatus 20 was provided in ten places, it is not limited to ten places.

FIG. 3A is a schematic diagram showing the vibration suppression apparatus 20 according to one embodiment of the present invention. As shown to FIG. 3A, the connection vibration damping apparatus 20 is equipped with the blast furnace mounting part 21, the furnace body frame mounting part 22, and the elastic vibration damping mechanism 23. As shown in FIG. This vibration damping mechanism 23 is connected between the blast furnace mounting portion and the furnace frame mounting portion.

The blast furnace attachment portion 21 is a three-layer structure including the blast furnace side mounting plate 30, the low friction plate 31, and the base plate 32. The low friction plate 31 is disposed between the blast furnace side mounting plate 30 and the base plate 32 and is attached to the base plate 32. The blast furnace side mounting plate 30 (blast furnace mounting portion 21) is provided with one end of the vibration suppression mechanism 23 by a pin joint 25 as a connecting member so that the vibration suppression mechanism 23 can rotate in the horizontal plane. 1 end). Moreover, the long hole 35 extended in the up-down direction (vertical direction) is formed in the blast furnace side mounting plate 30. The joining bolts 36 fixed to the base plate 32 and the low friction plate 31 are inserted into this long hole 35. Therefore, the blast furnace side mounting plate 30 can move to an up-down direction (vertical direction), making surface contact with the low friction plate 31. FIG. In addition, the blast furnace mounting part 21 is separable between the blast furnace side mounting plate 30 and the low friction plate 31.

Similarly, the furnace body frame attaching portion 22 is composed of a frame side mounting plate 40 and a frame side base plate 46. This frame side mounting plate 40 (the furnace frame mounting part 22) is connected with the other end part (2nd end part) of the damping mechanism 23 by the pin joint 26 which is a connection member. In addition, the body frame attaching part 22 is separable between the frame side mounting plate 40 and the frame side base plate 46. The frame side mounting plate 40 is fixed to the frame side base plate 46 by the joining bolt 41.

3B is a perspective view of the connection vibration suppression apparatus 20 which concerns on one Embodiment of this invention attached between the blast furnace main body 11 and the furnace frame 12, as shown in FIG. 3C is a side view (the view seen from the circumferential direction of the blast furnace main body 11) of the blast furnace mounting part 21 attached to the blast furnace main body 11. 3D is a side view (the view seen from the circumferential direction of the blast furnace main body 11) of the furnace frame attaching part 22 attached to the furnace frame 12. As shown in FIG. As shown to FIG. 3B and FIG. 3C, the base plate 32 (blast furnace attachment part 21) is fixed to the outer peripheral surface of the blast furnace main body 11 by the support member 33. As shown in FIG. Similarly, as shown in FIG. 3B and FIG. 3D, the frame side base plate 46 (the body frame attaching part 22) is the bottom beam 12b (the body frame 12) by the frame side support member 47. ] Is mounted on the inner side. Since the connection damping apparatus 20 which concerns on one Embodiment of this invention is the structure shown above, according to the magnitude | size of the clearance gap between the outer peripheral surface of the blast furnace main body 11, and the inner surface of the bottom beam 12b, the blast furnace main body 11 It is possible to easily mount the connection vibration suppression apparatus 20 between the floor beam 12b and the bottom beam 12b.

This vibration damping mechanism 23 absorbs vibration energy between the blast furnace body 11 and the furnace frame 12. Therefore, as a damping mechanism 23, flexible members, such as a hydraulic damper, an air damper, a forced hysteresis damper, a viscoelastic damper, are used, for example. In addition, below, the arrangement | positioning method of the connection damping apparatus 20 is demonstrated based on the expansion-contraction direction L of this damping mechanism 23. As shown in FIG. For example, in FIG. 2, the connection vibration damping apparatus 20 is arrange | positioned so that the expansion-contraction direction L of the vibration damping mechanism 23 may substantially correspond to the circumferential direction of the blast furnace main body 11.

In the blast furnace installation 1 in one Embodiment of this invention comprised as mentioned above, when there is an earthquake input, the damping effect is acquired by the effect of the connection damping apparatus 20. FIG. That is, with respect to the earthquake input in the horizontal direction, the vibration suppression mechanism 23 provided in each connection vibration suppression apparatus 20 is expanded and contracted. By this vibration damping mechanism 23, the vibration energy of the horizontal direction between the blast furnace main body 11 and the furnace frame 12 is absorbed, and the vibration damping effect of the horizontal direction is exhibited. In this case, since the some vibration damping mechanism 23 is provided in the circumference along the outer periphery of the blast furnace main body 11, the vibration damping mechanism 23 of each coupling | damping damping apparatus 20 of all directions in a horizontal plane is carried out. It can absorb earthquake input. On the other hand, with respect to the earthquake input in the vertical direction, in the blast furnace mounting portion 21 of each connection vibration suppression device 20, the blast furnace side mounting plate 30 moves in the vertical direction while being in surface contact with the low friction plate 31. That is, the blast furnace mounting part 21 is attached so that the damping mechanism 23 can move to an up-down direction with respect to the blast furnace main body 11. The blast furnace mounting portion 21 and the vibration suppression mechanism 23 absorb the vibration energy in the vertical direction between the blast furnace main body 11 and the furnace frame 12, and a vibration suppression effect in the vertical direction is obtained. Therefore, in the event of an earthquake, the horizontal and vertical bidirectional displacements generated in the blast furnace installation 1 (particularly the furnace frame 12) are absorbed by the plurality of vibration suppression apparatuses 20 and applied to the blast furnace installation 1. Seismic power is reduced.

Here, the blast furnace side mounting plate 30 moves in the vertical direction while being in surface contact with the low friction plate 31. Therefore, when a low friction plate 31 is used, for example, a Teflon (registered trademark) plate, an SUS plate, or the like, the friction coefficient between the blast furnace side mounting plate 30 and the low friction plate 31 can be lowered. Problems such as damage of the connection vibration suppression apparatus 20 can be avoided.

In addition, at the time of operation of the blast furnace installation 1, the heat deformation of about 100 mm may generate | occur | produce in the blast furnace main body 11 by the heat in a furnace. However, a low friction plate that uses pin joints 25 and 26 for mounting the vibration damping device 20 and can flexibly cope with thermal deformation between the blast furnace side mounting plate 30 and the outer circumferential surface of the blast furnace body 11 ( By providing 31), damage to the vibration suppression mechanism 23 due to thermal deformation of the blast furnace main body 11 at the time of operation of the blast furnace installation 1 is prevented. Similarly, damage to the vibration suppression mechanism 23 due to thermal deformation of the blast furnace body 11 accompanying cooling at the time of stopping the blast furnace installation 1 is also prevented.

In addition, in the blast furnace installation 1, reconstruction work is performed suitably for the increase of the capacity of a blast furnace, and improvement of an operation efficiency. Since the seismic performance of the blast furnace installation 1 is improved by using the connection vibration suppression apparatus 20 which concerns on embodiment of this invention, the magnitude | size of earthquake-proof reinforcement construction is reduced compared with the past, and efficiency in terms of construction period, construction cost, etc. is improved. It is planned. Moreover, since the load applied to the blast furnace installation base 10 at the time of earthquake-proof reinforcement construction can be reduced, reinforcement etc. of the installation base 10 can be reduced. Similarly, in blast furnace new construction, efficiency can be achieved in terms of construction period, construction cost, and the like.

In the above embodiment, the pin joint 25 and the pin joint 26 are used for the connection between the vibration suppression mechanism 23 and the blast furnace body 11 and the connection between the vibration suppression mechanism 23 and the furnace frame 12, respectively. Doing. However, the present invention is not limited to this connection method (connection structure). For example, as shown in FIG. 4A, the ball joint 45 may be used to connect the blast furnace mounting portion 21 and the vibration suppression mechanism 23 and to connect the frame mounting portion 22 and the vibration suppression mechanism 23. In this case, the ball joint main body 45a is directly attached to the blast furnace side mounting plate 30 and the frame side mounting plate 40. Since the arm 45b of the ball joint 45 is rotatable in all directions (in the horizontal plane and in the vertical plane), the blast furnace side mounting plate 30 is directly fixed to the base plate 32 by the joining bolts 36, The low friction plate 31 may be omitted. That is, what is necessary is just to combine the connection member, such as a pin joint and a ball joint, and the blast furnace mounting part 21 or the frame mounting part 22 so that the damping mechanism 23 can expand and contract in all directions (horizontal direction and vertical direction). However, it is preferable to use a connection member having an axis (arm) that is rotatable at least in a horizontal plane for the connection between the vibration suppression mechanism 23 and the blast furnace body 11 and the connection between the vibration suppression mechanism 23 and the furnace frame 12. .

4B is a perspective view of the connection vibration suppression apparatus 20 according to one embodiment of the present invention when the ball joint 45 is used as the connecting member. As shown in FIG. 4B, the blast furnace side mounting plate 30 (blast furnace mounting unit 21) and the frame side mounting plate 40 (frame mounting unit 22) are the blast furnace main body 11 and the furnace frame 12, respectively. ) (Floor 12b). However, since the damping mechanism 23 of the connection damping apparatus 20 can be expanded and contracted by the ball joint 45 in all directions (horizontal direction and vertical direction), the damping effect is exhibited with respect to the earthquake input from all directions.

In addition, in the above-described embodiment, as shown in FIG. 2, although the vibration damping mechanism 23 arrange | positioned so that the circumferential direction of the blast furnace main body 11 may be arrange | positioned, this invention is this arrangement method. It is not limited to. An example thereof will be described below with reference to FIG. 5.

5 is an explanatory diagram illustrating an arrangement example of the connection vibration suppression apparatus 20. FIG. 6: A is a perspective view of the connection damping apparatus 20 which concerns on one Embodiment of this invention attached between the blast furnace main body 11 and the furnace frame 12, as shown in FIG. 6B is a perspective view of the connection vibration suppression apparatus 20 according to the embodiment of the present invention when a ball joint is used as the connecting member. In the embodiment shown in FIG. 5, the plurality of coupled vibration suppression apparatuses 20 (nine places in FIG. 5) are arranged such that the expansion and contraction direction L of the vibration suppression mechanism 23 is in the radial direction of the blast furnace main body 11. Is placed. Also in this arrangement, similarly to the embodiment shown in FIG. 2, when an earthquake occurs, horizontal and vertical bidirectional directions generated in the blast furnace installation 1 (particularly the furnace frame 12) by the plurality of connection vibration suppression apparatuses 20. Displacement is absorbed and the seismic force applied to the blast furnace installation 1 is reduced. In addition, in the arrangement example of the connection vibration suppression apparatus 20 shown to FIG. 5 and FIG. 6A, since the pin joint 25, the pin joint 26, and the vibration damping mechanism 23 are arrange | positioned in a straight line, it is shown in FIG. Compared with the case of embodiment, the connection vibration suppression apparatus 20 can be installed easily. In addition, in the example of arrangement | positioning of the connection damping apparatus 20 shown to FIG. 5, FIG. 6A, and FIG. 6B, addition and exchange of the connection damping apparatus 20 can be performed flexibly.

In addition, in embodiment shown to FIG. 2, FIG. 3A, and FIG. 4, the space for installing the connection vibration damping apparatus 20 can be reduced. Therefore, also in the blast furnace installation 1 which has a narrow space | interval between the blast furnace main body 11 and the floor beam 12b, it becomes possible to provide the some vibration damping apparatus 20. FIG.

That is, in order to make installation of the connection damping apparatus 20 as easy as possible, you may arrange | position the connection damping apparatus 20 so that the expansion-contraction direction of the vibration damping mechanism 23 may include the radial direction of the blast furnace main body 11. In addition, you may arrange | connect the connection damping apparatus 20 so that the expansion-contraction direction of the damping mechanism 23 may include the circumferential direction of the blast furnace main body 11 according to the space between the blast furnace main body 11 and the bottom beam 12b. In this manner, the angle formed between the expansion and contraction direction of the vibration suppression mechanism 23 and the radial direction of the blast furnace main body 11 can be arbitrarily determined according to the gap between the blast furnace main body 11 and the bottom beam 12b. In addition, you may combine embodiment shown in FIG. 2 and embodiment shown in FIG.

In addition, it is preferable that the vibration damping apparatus 20 is provided in multiple numbers in the blast furnace installation 1. In this case, in order to respond to earthquake inputs from all directions in the horizontal plane, at least two of the plurality of coupled vibration suppression apparatuses 20 are preferably mounted on the outer circumferential surface of the blast furnace body 11 so as to be substantially orthogonal. Therefore, as shown, for example in FIG. 7, two connection vibration damping apparatuses 20 may be sufficient.

Example

MEANS TO SOLVE THE PROBLEM In the blast furnace installation 1 of the steel mill, this inventor analyzed the vibration damping response at the time of installing the connection damping apparatus 20 shown in the said embodiment at each height of a blast furnace. Below, the analysis result is demonstrated with reference to drawings.

8 is a schematic view of the blast furnace installation 1 showing the position where the connection vibration suppression apparatus 20 is installed. The height of the blast furnace main body 11 is about 50 m. In addition, the installation location of the connection vibration suppression apparatus 20 is any one of the positions of the height 25m bottom, 35m bottom, 41m bottom, and 49m bottom in the furnace frame 12. As shown in FIG. In addition, the arrangement | positioning method of the connection damping apparatus 20 is the same as that of embodiment shown in FIG. Under these conditions, the horizontal displacements of the blast furnace body 11 and the furnace frame 12 during the earthquake were analyzed. The graph which shows the analysis result is FIG. In addition, the assumed level of an earthquake is 25 cm / s, 200 gal and magnitude about 5.

As shown in FIG. 9, the horizontal displacement of the blast furnace body 11 is smaller than the horizontal displacement of the furnace frame 12. In addition, since the horizontal displacement of the blast furnace main body 11 hardly depends on the installation location (installation height) of the connection damping apparatus 20, it is represented by one curve data. In addition, as shown in FIG. 9, the horizontal displacement of the furnace frame 12 in the case where the connection vibration suppression device 20 is installed at a position of 25 m bottom is compared with the case where the connection vibration suppression device 20 is not installed. , 27.4%. Similarly, when the connection vibration suppression apparatus 20 was provided in the position of 35m bottom, the horizontal displacement of the furnace frame 12 was reduced by 48.8%. In addition, when the connection vibration suppression apparatus 20 was provided in the position of 41m floor or 49m floor, the horizontal displacement of the furnace frame 12 was reduced 58% or more. The analysis result showed that the preferable installation position of the connection damping apparatus 20 is as follows. That is, as for the installation position of the connection damping apparatus 20, the height (position) of 1/2 or more of the height of the blast furnace main body 11 is preferable. Moreover, as for the installation position of the connection vibration damping apparatus 20, the position of the height more than 35m floor (height of 35m from the bottom of the blast furnace main body 11) is more preferable.

In addition, in FIG. 10, when the retrofit which expands the blast furnace installation 1 of a phenomenon is shown, the schematic diagram which showed the burden load exerted on the blast furnace base 10 at the time of an earthquake by bar graph was shown. Here, in the comparative example shown by "a", the blast furnace installation 1 was remodeled without providing the connection vibration damper 20. In the example shown by "b", the connection vibration suppression apparatus 20 of one Embodiment of this invention shown to FIG. 3A was installed in 41m floor, and the blast furnace installation 1 was remodeled. In addition, "w" is a state (development) before remodeling.

As shown in FIG. 10, in the comparative example, the intensity burden applied to the blast furnace base 10 by enlargement and remodeling greatly increases, and large scale reinforcement is required. However, by employing the vibration suppression structure of the present invention as in the embodiment, even when the expansion and remodeling is performed, the burden load applied to the blast furnace foundation 10 satisfies the allowable value of the strength required for the blast furnace foundation 10 ( Below the permissible value). In addition, in the Example, it turned out that the effect which reduces the burden load applied to the blast furnace base 10 rather than a phenomenon can be exhibited. Similarly, since the seismic energy input to the furnace frame 12 is reduced, it has also been found that the reinforcement of major structural members such as columns, beams, and braces can be greatly reduced.

As mentioned above, although an example of embodiment of this invention was described, this invention is not limited to the form shown in drawing. It is apparent to those skilled in the art that various modifications or modifications can be conceived within the scope of the spirit described in the claims, and that they naturally belong to the technical scope of the present invention.

INDUSTRIAL APPLICABILITY The present invention can be applied to a blast furnace facility having improved seismic performance, a method for improving seismic performance of a blast furnace facility, and a connection vibration suppression device for improving the seismic performance of the blast furnace facility.

1: blast furnace equipment
10: equipment base
11: blast furnace body
12: nobody frame
12a: body frame body
12b: Floorcloth
20: connection damping device
21: blast furnace mounting
22: body frame mounting
23: damping mechanism
25: pin joint
26: pin joint
30: blast furnace side mounting plate
31: low friction plate
32: Foundation Edition
33: support member
35: long hole
36: joint bolt
40: frame side mounting plate
41: joint bolt
45: ball joint
45a: ball joint body
45b: arm
46: frame side base plate
47: frame side support member

Claims (8)

So with the body,
The furnace frame surrounding the blast furnace body,
A blast furnace installation, characterized in that it is provided at a position of 1/2 or more of the height of the blast furnace body, and comprising a connection vibration suppression device for connecting between the blast furnace body and the furnace frame. According to claim 1, The connection vibration suppression device,
And blast furnace mounting portion mounted to the blast furnace body,
A body frame mounting portion mounted to the body frame,
A stretchable vibration damping mechanism connected between the blast furnace mount and the furnace frame mount;
The blast furnace installation characterized by the above-mentioned blast furnace main body being mounted so that the expansion and contraction direction of the said vibration damping mechanism may include the circumferential direction of the said blast furnace main body. According to claim 1, The connection vibration suppression device,
And blast furnace mounting portion mounted to the blast furnace body,
A body frame mounting portion mounted on the body frame,
A stretchable vibration damping mechanism connected between the blast furnace mount and the furnace frame mount;
The blast furnace installation characterized by the above-mentioned. The blast furnace installation according to claim 2 or 3, wherein the blast furnace mounting portion is mounted to the blast furnace body such that the vibration suppression mechanism is movable in the vertical direction. It is a method of improving the seismic performance of the blast furnace installation having a blast furnace body and a furnace frame surrounding the blast furnace body,
A seismic damper for connecting the blast furnace body and the furnace frame is provided at a position of 1/2 or more of the height of the blast furnace body, wherein the seismic performance is improved. According to claim 5, The connection vibration suppression device,
And blast furnace mounting portion mounted to the blast furnace body,
A body frame mounting portion mounted on the body frame,
A stretchable vibration damping mechanism connected between the blast furnace mount and the furnace frame mount;
The seismic performance improvement method characterized by being mounted to the said blast furnace main body so that the expansion-contraction direction of the said vibration damping mechanism may include the circumferential direction of the said blast furnace main body. According to claim 5, The connection vibration suppression device,
And blast furnace mounting portion mounted to the blast furnace body,
A body frame mounting portion mounted to the body frame,
A stretchable vibration damping mechanism connected between the blast furnace mount and the furnace frame mount;
The seismic performance improvement method characterized by being mounted to the said blast furnace main body so that the expansion-contraction direction of the said vibration damping mechanism may include the radial direction of the said blast furnace main body. The blast furnace attachment part attached to the blast furnace body,
A furnace frame mounting portion mounted to the furnace frame supporting the blast furnace body,
And a stretchable vibration damping mechanism connected between the blast furnace mount and the furnace frame mount.

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