JP4302006B2 - Boiler equipment - Google Patents

Description

  The present invention relates to a boiler facility in which a chimney is disposed on an upper portion of a boiler support frame that supports a boiler can.

  With the increase in the size of boiler facilities, various technologies for suppressing vibrations in the boiler facilities caused by wind and earthquake have been developed. As an example of a conventional boiler facility that performs such a technique, a patent document 1 discloses a boiler support structure. In this boiler support structure, the side of the boiler body suspended from the upper part of the boiler support frame and the boiler support frame are connected by an extremely fine trigger, and an attenuator is provided between the lower part of the boiler body and the ground. It has been. The ultra-thin trigger suppresses vibration of the boiler body during normal operation, vibration of the boiler body due to wind, and the like, and the attenuator suppresses vibration of the boiler body during an earthquake.

  As another example of the conventional boiler equipment, the following Patent Document 2 discloses a boiler structure including a semi-active dynamic vibration absorber. The boiler structure including the semi-active dynamic vibration absorber includes a spring, a variable damping damper, and an additional mass that are combined in parallel and attached to the structure. The boiler structure is controlled by controlling a damping coefficient of the variable damping damper so as to generate a damping force represented by a product of a relative displacement between the structure and the additional mass and a proportional constant of the damper applied to the relative displacement. The vibration of the object is suppressed.

Japanese Utility Model Publication No. 5-45404 JP-A-10-246279

  In the conventional boiler equipment, a boiler can, a boiler support frame that suspends and supports the boiler can, a chimney that discharges exhaust gas generated by the boiler can, and a chimney support frame that supports the chimney, respectively Although it was installed on the ground, there is a structure in which the chimney and the chimney support frame are installed above the boiler support frame from the viewpoint of space saving of the land and rationalization of the boiler structure. However, as the boiler equipment is structured as described above, the response at the time of earthquake at the base of the boiler support frame, that is, the shearing force in the horizontal direction becomes larger than that of the conventional boiler support frame. Therefore, in order to make the boiler support frame to withstand the shearing force, it is necessary to enlarge the basic structure of the boiler support frame, and there is a problem that the construction cost of the boiler equipment increases.

  The boiler support structure described in Patent Document 1 and the boiler structure including the quasi-active dynamic vibration absorber described in Patent Document 2 are intended for anti-seismic and vibration control measures for a single boiler. It is not assumed for the structure where the chimney is arranged on the top of the.

  Furthermore, the dynamic vibration absorber used in the boiler structure described in Patent Document 2 is a quasi-active type, and since it is installed outdoors, it becomes necessary to perform maintenance and inspection of the quasi-active type dynamic vibration absorber. When an earthquake or the like occurs, electric power is not supplied to a control system such as a control device that controls the quasi-active dynamic vibration absorber, and the quasi-active dynamic vibration absorber may not operate.

  Therefore, the present invention has been proposed in view of the above-described problems, and it is not necessary to perform maintenance and inspection. Further, the boiler equipment has always improved the earthquake resistance without causing an increase in construction cost without causing the earthquake resistance to function. The purpose is to provide.

The boiler facility according to the first invention for solving the above-described problem is
A boiler can, a boiler support frame that suspends and supports the boiler can, a chimney disposed on an upper portion of the boiler support frame, and a chimney support frame that supports the chimney ,
A flange is provided on the outer periphery of the chimney, the shaft is passed through the flange from the chimney support frame side, a gap is provided between the flange and a stopper is provided on the shaft, and the chimney is attached to the chimney support frame. It is characterized by being supported so as to be swingable .

The boiler equipment according to the second invention for solving the above-described problem is
The boiler facility described in the first invention,
The shaft is a bolt, and the stopper is a nut.

The boiler equipment according to the third invention for solving the above-described problem is
The boiler equipment described in the first invention or the second invention ,
A damping mechanism is interposed between the chimney and the chimney support frame.

The boiler facility according to the fourth invention for solving the above-described problem is
The boiler equipment described in the third invention,
A second damping mechanism is interposed between the boiler can and the boiler support frame.

The boiler facility according to the fifth invention for solving the above-described problem is
The boiler facility described in the third invention or the fourth invention,
The damping mechanism and the second damping mechanism each include a second elastic member and a damping damper arranged in parallel.

The boiler facility according to the sixth invention for solving the above-described problem is as follows.
The boiler facility described in the fifth invention,
The damping damper is a viscous damper.

The boiler facility according to the seventh invention for solving the above-described problem is
The boiler equipment according to any one of the third to sixth inventions,
The damping mechanism is arranged at a position different from a position at which the chimney is swingably supported by the chimney support frame.

The boiler equipment according to the eighth invention for solving the above-described problem is
The boiler equipment according to any one of the third to sixth inventions,
The damping mechanism is arranged at a position farthest from a position at which the chimney is swingably supported by the chimney support frame.

According to the boiler facility according to the first aspect of the invention, the boiler can, the boiler support frame that suspends and supports the boiler can, the chimney that is disposed above the boiler support frame, and the chimney support that supports the chimney The chimney swings with respect to the chimney support frame when vibration such as an earthquake propagates to the chimney. Since the vibration energy is consumed and reduced by using the motion, the earthquake resistance of the boiler equipment is improved. In addition, since the chimney is only supported swingably on the chimney support frame, there is no need to perform maintenance and inspection, and the earthquake resistance of the boiler equipment can always be functioned. Furthermore, since it is not necessary to enlarge the basic structure of boiler equipment, construction costs are reduced.
A flange is provided on the outer periphery of the chimney, the shaft is passed through the flange from the chimney support frame side, a gap is provided between the flange and a stopper is provided on the shaft, and the chimney is attached to the chimney support frame. By making it swingable, when a vibration such as an earthquake propagates to the chimney, the flange can swing to the position of the stopper. Therefore, the vibration energy is consumed and reduced by the swing of the flange, so that the earthquake resistance of the boiler equipment is improved.

According to the boiler equipment according to the second invention, the boiler equipment described in the first invention, wherein the shaft is a bolt and the stopper is a nut, and is therefore commercially available. Cost is reduced.

According to the boiler facility according to the third invention, the boiler facility according to the first invention or the second invention , wherein a damping mechanism is interposed between the chimney and the chimney support frame. When the vibration propagates to the chimney, the damping mechanism absorbs the energy of the vibration, and the chimney, the chimney support frame, and the boiler support frame vibrate in synchronism. Improves.

According to the boiler facility according to the fourth invention, the boiler facility according to the third invention, wherein a second damping mechanism is interposed between the boiler can and the boiler support frame. When a vibration such as an earthquake propagates to the boiler can, the second damping mechanism absorbs the energy of the vibration, and the boiler can and the boiler support frame vibrate in synchronization. Improves earthquake resistance.

According to the boiler equipment pertaining to the fifth invention, the boiler equipment described in the third invention or the fourth invention, wherein the damping mechanism and the second damping mechanism are respectively arranged in parallel. Since the second elastic member is composed of two elastic members and a damping damper, the second elastic member suppresses shaking of the boiler can and chimney due to wind during normal operation or wind, and the damping damper propagates to the boiler can. Since the vibration of the boiler can and the chimney are suppressed by absorbing the force of this and the force such as the earthquake propagated to the chimney, the earthquake resistance of the boiler equipment is improved.

According to the boiler facility pertaining to the sixth invention, the boiler facility according to the fifth invention, wherein the damping damper is a viscous damper, so that it is possible to easily adjust the amount of displacement energy to be absorbed. it can.

According to the boiler facility pertaining to the seventh invention, the boiler facility according to any one of the third to sixth inventions, wherein the chimney is pivotally supported by the chimney support frame; By disposing the damping mechanism at different positions, the front damping mechanism can be easily disposed, and the construction cost of the boiler equipment is suppressed.

According to the boiler facility relating to the eighth invention, the boiler facility according to any one of the third to sixth inventions, wherein the chimney is pivotally supported by the chimney support frame. By disposing the damping mechanism at the farthest position, when a force such as an earthquake propagates to the chimney, the force is located farthest from the position at which the chimney is swingably supported by the chimney support frame. Although it acts, since the damping mechanism is arranged at this position, the force is suppressed by the damping mechanism, and the earthquake resistance of the boiler equipment is improved.

  Below, the best form for implementing the boiler equipment which concerns on this invention is demonstrated.

  FIG. 1 is a schematic view of boiler equipment according to an embodiment of the present invention, and FIG. 2 is a side view of a chimney support structure used therefor. 3 is a cross-sectional view taken along the line III-III in FIG. FIG. 4 is a plan view showing a state in which a damping mechanism is installed in one embodiment of a chimney support frame used in boiler equipment according to one embodiment of the present invention, and FIG. 5 is a boiler according to one embodiment of the present invention. It is a top view of the state which installed the damping mechanism in other embodiment of the chimney support frame used for an installation. FIG. 6 is a side view showing another embodiment of the chimney support structure used in the boiler equipment according to one embodiment of the present invention. FIG. 7 shows still another embodiment of the chimney support structure used in the boiler equipment which is an embodiment of the present invention, where (a) is a plan view thereof and (b) is a side view thereof.

  As shown in FIG. 1, a boiler facility 23 is disposed on a boiler can (not shown), a boiler support frame 1 that suspends and supports the boiler can, and an upper portion of the boiler support frame 1. A chimney 2 that discharges the generated exhaust gas and a chimney support frame 3 that supports the chimney 2 are provided. The boiler support frame 1 and the chimney support frame 3 are made of steel or the like. The lower part of the chimney support frame 3 is fixed to the boiler support frame 1 with bolts (not shown). The chimney support frame 3 is formed by assembling a vertical member 4 extending in a substantially vertical direction, a horizontal member 5 extending in a horizontal direction, and an oblique member 6 extending in a diagonal direction. The boiler support frame 1 is composed of a vertical member 1a extending in the vertical direction, a horizontal member 1b extending in the horizontal direction, and a plurality of oblique members 1c extending in the obliquely up and down direction. It has the strength to support the chimney support frame 3. In the chimney support frame 3 described above, the horizontal members 5 are arranged in five stages in the vertical direction.

  As shown in FIGS. 1 and 2, the chimney support structure 12 that supports the chimney 2 on the chimney support frame 3 so as to be swingable is disposed in contact with the upper part of the second horizontal member 5.

  As shown in FIG. 3, the second-stage horizontal member 5 includes an outer horizontal member 5 a arranged outside the chimney 2 and connecting the adjacent vertical members 4, the outer horizontal member 5 a, and the chimney 2. And an inner horizontal member 5b arranged by connecting substantially the center portions of the adjacent outer horizontal members 5a and an innermost horizontal member 5c having a substantially rectangular shape whose corners are joined to the inner horizontal member 5b. Have. As shown in FIG. 4, the level material other than the second level horizontal material 5 includes a horizontal material having an outer horizontal material 5 a arranged outside the chimney 2 and connecting the adjacent vertical materials 4 to each other. 5 and an outer horizontal member 5a arranged on the outside of the chimney 2 and connecting the adjacent vertical members 4 to each other, and between the outer horizontal member 5a and the chimney 2, as shown in FIG. There is a horizontal member 5 having a structure composed of an inner horizontal member 5b arranged by connecting substantially the center portions of the outer horizontal member 5a.

  2 and 3, the chimney support structure 12 is fixed to the outer periphery 2a of the chimney 2 and extends to the vicinity of the second-stage horizontal member 5 in the chimney support frame 3. 13 and a lower ring flange (flange) 14 provided below the upper ring flange 13 and fixed to the outer periphery 2a of the chimney 2 and extending to the vicinity of the second horizontal member 5 in the chimney support frame 3. Ribs 15 are provided to fix the upper ring flange 13 and the lower ring flange 14 at a predetermined interval. A plurality of the ribs 15 are arranged at a predetermined interval. By forming the chimney support structure 12 as described above, the chimney support structure 12 can be arranged on the upper part of the second level horizontal member 5 in the chimney support frame 3, and the chimney 2 is supported by the chimney support via the chimney support structure 12. Supported by the frame 3.

  A plurality of bolts 16 serving as shafts are arranged at predetermined intervals at positions on the upper and lower ring flanges 13 and 14 that are concentric with the chimney 2. These bolts 16 pass through the lower ring flange 14 and the upper ring flange 13 from the second level horizontal member 5 side in the chimney support frame 3, and a nut serving as a stopper with a gap between the upper ring flange 13 and the bolt 16. 17 is fastened and fixed by welding. Since the said axis | shaft is the volt | bolt 16 and the said stopper is the nut 17, it is marketed and the construction cost of the boiler equipment 23 is suppressed. The shaft is not limited to the bolt 16 and may be a rod-shaped member. The rod-shaped member is provided through the lower ring flange 14 and the upper ring flange 13 from the second-stage horizontal member 5 side in the chimney support frame 3, and one end side of the rod-shaped member is disposed on the second-stage horizontal member. The chimney 2 can be swingably supported on the chimney support frame 3 by being fixed to 5 by welding and providing the stopper with a gap between the upper ring flange 13 and the other end. The stopper is not limited to a nut, and may be a plate-like member. A gap is formed between the plate-like member and the upper ring flange 13 on the other end side of the shaft passing through the lower ring flange 14 and the upper ring flange 13 from the second-stage horizontal member 5 side in the chimney support frame 3. By providing a gap, the upper ring flange 13 will not come off the shaft. The bolt 16 is fixed to the second horizontal member 5 in the chimney support frame 3 by welding. By fastening the nut 17 to the bolt 16 in this way, the chimney 2 is supported by the chimney support frame 3 so as to be swingable.

  Specifically, when a vibration such as an earthquake propagates to the chimney 2 and the one side 12 a side of the chimney support structure 12 is supported by the second horizontal member 5 in the chimney support frame 3, the chimney support structure 12. On the other side 12b side opposite to the one side 12a, the upper ring flange 13 is lifted up to a position where it contacts the nut 17, and conversely, the other side 12b of the chimney support structure 12 is the second stage in the chimney support frame 3. When supported by the horizontal member 5, the upper ring flange 13 is lifted up to a position where the upper ring flange 13 is in contact with the nut 17 on one side 12 a side of the chimney support structure 12. That is, the chimney 2 is supported by the chimney support frame 3 so as to be swingable while allowing a swinging range. When the chimney support structure 12 has such a structure, when a force such as an earthquake propagates to the chimney 2, the chimney 2 swings with respect to the chimney support frame 3, and the energy of the force is consumed by the swing. Therefore, the earthquake resistance of the boiler equipment 23 is improved. In addition, since the chimney support structure 12 is simply constructed as described above, there is no need for maintenance and inspection, and the earthquake resistance can always be functioned.

  The chimney support frame 3 includes a stairway 18 that can be lifted and lowered by an operator who maintains and checks the chimney 2, and a scaffold for the worker when the chimney 2 is inspected and extended from the staircase 18 to the vicinity of the chimney 2. Step 19 is provided.

  The chimney support structure 12 is not limited to the above structure. As shown in FIG. 6, the chimney support structure 33 is fixed to the outer periphery of the chimney 2 and extends to the vicinity of the horizontal member 5 of the chimney support frame 3, and the lower part of the horizontal member 5 of the chimney support frame 3. The other end 31b of the spring 31 is fixed to the flange 30 with a pin 32. The spring 31 is a first elastic member to which one end 31a is connected. That is, the flange 30 is supported by being suspended via the spring 31 connected to the horizontal member 5. A plurality of springs 31 are arranged at predetermined intervals at positions on the flange 30 that are concentric with the chimney 2. When the spring 31 is interposed between the horizontal member 5 of the chimney support frame 3 and the flange 30 fixed to the chimney 2 as described above, when a force such as an earthquake propagates to the chimney 2, the chimney is caused by the force. 2 and the flange 30 are swayed, and the spring 31 is swayed in response to this sway, and the energy of the force is consumed and reduced by this swaying, so that the earthquake resistance of the boiler equipment is improved. However, the flange 30 swings within a range that the length of the spring 31 allows. That is, the chimney 2 is supported by the chimney support frame 3 so as to be swingable while allowing a swinging range. Further, as shown in FIG. 7, shock absorbers 24 such as laminated rubber are installed at a predetermined interval between the lower ring flange 14 of the chimney support structure 12 and the horizontal member 5 to reduce noise during swinging. A structure is also conceivable.

As shown in FIGS. 4 and 5, the displacement energy of the chimney 2 is absorbed at a position different from the position where the chimney support structure 12 is arranged, that is, at a stage other than the second level horizontal member 5. A damping mechanism 22 that synchronizes the frame 1 with the chimney 2 and the chimney support frame 3 is disposed. The damping mechanism 22 is arranged in parallel, and includes a spring 20 that is a second elastic member that connects the chimney 2 and the horizontal member 5 of the chimney support frame 3, and a viscous damper 21 that is a damping damper. Specifically, the damping mechanism 22 is arranged by connecting the chimney 2 and the substantially central portion of the outer horizontal member 5a as shown in FIG. 4, or the chimney 2 and the inner horizontal member as shown in FIG. 5b is connected to the substantially central portion. Examples of the viscous damper 21 include an oil damper. By using the damping damper as the viscous damper 21, it is possible to easily adjust the amount of displacement energy to be absorbed. Instead of the spring 20 and the viscous damper 21, a steel damper such as a leaf spring or a viscoelastic damper may be used. Examples of the viscoelastic damper include a damper using a silicon rubber material, a urethane asphalt rubber material, a diene rubber material, or the like, which is a viscoelastic material (polymer material). The chimney 2 is supported on the chimney support frame 3 by the spring 20, and the chimney 2 is prevented from shaking due to normal operation and wind. By absorbing the displacement energy of the chimney 2 by the force of an earthquake propagated to the chimney 2 by the viscous damper 21, the chimney 2 and chimney support Frames 3, such that the boiler and the boiler supporting Frames 1 vibrates in sympathy Become. Further, the chimney 2 and the chimney support frame 3 and the boiler can and the boiler support frame 1 are vibrated in synchronization with each other by the spring 20, and the chimney 2 and the chimney 2 due to the force such as an earthquake propagated to the chimney 2 by the viscous damper 21. Energy is absorbed using the relative displacement of the material 5.

  Therefore, according to the boiler equipment 23 described above, by arranging the damping mechanism 22, the natural frequency of the entire chimney composed of the chimney 2 and the chimney support frame 3 and the natural frequency of the boiler support frame 1 are synchronized. Alternatively, the damping mechanism 22 functions as an energy absorbing vibrator, so that the shearing force at the base of the boiler equipment 23 is reduced, and the earthquake resistance of the boiler equipment 23 is improved. Moreover, since the earthquake resistance of the whole boiler equipment 23 improves by making the boiler equipment 23 the structure as mentioned above, it is not necessary to enlarge the boiler equipment 23 and the construction cost of the boiler equipment 23 is suppressed. .

  In the above description, the chimney support structure 12 is supported by the second-stage horizontal member 5 in the chimney support frame 3, but may be supported by the horizontal member 5 disposed at another stage in the chimney support frame 3. Further, a second damping mechanism that absorbs the displacement energy of the boiler can and connects the boiler can and the boiler support frame 1 may be provided between the boiler can and the boiler support frame 1. Similar to the damping mechanism 22, the second damping mechanism includes a spring 20 that is arranged in parallel and connects the boiler can and the boiler support frame 1 and a viscous damper 21 that is a damping damper. By disposing the second damping mechanism at such a position, it is possible to suppress shaking of the boiler can during normal operation and due to wind and the like, and the boiler due to a force such as an earthquake propagated to the boiler can. By absorbing the displacement energy of the can, the boiler can and the boiler support frame 1 vibrate and vibration of the boiler can be suppressed, so that the earthquake resistance of the boiler equipment is further improved. Further, in the above description, the damping mechanism 22 is arranged in a stage other than the second-stage horizontal member 5 in the chimney support frame 3, but the uppermost horizontal member 5 and the chimney 2 farthest from the second-stage horizontal member 5 The damping mechanism 22 may be disposed between the two. By disposing the damping mechanism 22 at such a position, when a force such as an earthquake propagates to the chimney 2, the force is applied to the uppermost horizontal member 5 that supports the chimney 2 swingably on the chimney support frame 3. Although acting, since the damping mechanism 22 is disposed between the uppermost horizontal member 5 and the chimney 2, the force is suppressed by the damping mechanism 22, and the earthquake resistance of the boiler equipment 23 is improved.

  The spring constant of the spring 20 used in the damping mechanism 22 and the second damping mechanism described above, and the damping coefficient of the viscous damper 21 are the position at which the chimney 2 is supported by the chimney support frame 3, the chimney 2, the chimney support frame 3, It is calculated so as to be optimal according to the weight and size of the boiler can and the boiler support frame 1.

  Below, the best form for implementing the boiler equipment which concerns on this invention is demonstrated concretely based on an Example. The boiler equipment including the spring constant of the spring used for the damping mechanism calculated by the simulation and the damping coefficient of the viscous damper will be described below. Note that the numerical values calculated by simulation are given as examples only to help understanding of the invention.

  Below, the boiler equipment which concerns on the 1st Example of this invention is demonstrated. This boiler facility has the same structure as the boiler facility according to the best mode for carrying out the invention, and the same members are denoted by the same reference numerals and the description thereof is omitted. FIG. 8 is a schematic view of the boiler equipment according to the first embodiment of the present invention, and FIG. 9 is a perspective view of a boiler support frame used for the boiler equipment.

In the boiler equipment according to the first embodiment of the present invention, the chimney 2 is supported by the chimney support structure 12 disposed on the second horizontal member 8 of the chimney support frame 3, as shown in FIG. The height H ₁ of the chimney 2 is 48 m and its weight is 145 ton. The height H ₂ of the chimney support frame 3 is 24 m, and its weight is 127 tons.

  Between the boiler can (not shown) and the boiler support frame 1, a second damping mechanism including a spring 20 and a viscous damper 21 connecting the boiler can and the boiler support frame 1 is disposed. The weight of the boiler can is 3557 tons. As shown in FIG. 9, the boiler support frame 1 has a width w of 27.2 m, a depth d of 22.6 m, a height h of 52.15 m, and a weight of 1840 ton. .

The height h ₁ between the lowermost horizontal member 7 and the second horizontal member 8 adjacent above the lowermost horizontal member 7 is 6 m. The height h ₂ between the third horizontal member 9 adjacent above the horizontal member 8 is 6 m, and adjacent to the third horizontal member 9 and the third horizontal member 9. The height h ₃ between the fourth horizontal member 10 and the fourth horizontal member 10 is 6 m, and the fourth horizontal member 10 and the uppermost horizontal member 11 adjacent above the fourth horizontal member 10 are The height h ₄ between them is 6 m.

  A damping mechanism 22 including a spring 20 and a viscous damper 21 that connect the chimney 2 and the chimney support frame 3 is disposed between the horizontal members 7, 9, 10, 11 of each stage and the chimney 2. The spring constant of the spring 20 and the damping coefficient of the viscous damper 21 are adjusted as shown in Table 1 below.

  The shearing force at the base of the boiler equipment 41 is 38416 kN before taking countermeasures. Specifically, after taking countermeasures, the chimney 2 is placed on the second horizontal member 8 of the chimney support frame via the chimney support structure 12. The damping mechanism 22 is interposed between the horizontal members 7, 9, 10, 11 of the other stage of the chimney support frame 3 and the chimney 2, and the first member is interposed between the boiler can and the boiler support frame 1. It was 22765 kN when two damping mechanisms were interposed. Therefore, the chimney 2 is supported by the chimney support structure 12 disposed on the second level horizontal member 8 of the chimney support frame 3, and the horizontal members 7, 9, 10, 11 and the chimney 2 of each level of the chimney support frame 3. Are disposed between the spring 20 having a predetermined spring constant and the viscous damper 21 having a predetermined damping coefficient, so that the natural frequency of the entire chimney composed of the chimney 2 and the chimney support frame 3 and the boiler support frame are set. The natural frequency of 1 is synchronized, or the damping mechanism 22 and the second damping mechanism function as an energy absorbing vibrator, so that the shear force at the base of the boiler equipment 41 is reduced, and the earthquake resistance of the boiler equipment 41 is reduced. Will improve. Moreover, since the earthquake resistance of the boiler equipment 41 whole improves by making the boiler equipment 41 the above-mentioned structure, it is not necessary to enlarge the boiler equipment 41 and the construction cost of the boiler equipment 41 is suppressed. .

  Below, the boiler installation which concerns on the 2nd Example of this invention is demonstrated concretely using figures. The boiler equipment which concerns on a 2nd Example changes the arrangement position of the chimney support structure in the boiler equipment which concerns on a 1st Example mentioned above, and has the same structure as this boiler equipment. Since the boiler can, the boiler support frame, the chimney, and the structure of the chimney support frame have the same structure as the boiler equipment according to the first embodiment, the same members are denoted by the same reference numerals and the description thereof is omitted.

  FIG. 10 is a schematic view of boiler equipment according to the second embodiment of the present invention.

  In the boiler facility according to the second embodiment of the present invention, as shown in FIG. 10, the chimney 2 is supported by a chimney support structure 12 arranged on the horizontal member 7 at the lowest stage of the chimney support frame 3. Between the boiler can (not shown) and the boiler support frame 1, a second damping mechanism including a spring 20 and a viscous damper 21 connecting the boiler can and the boiler support frame 1 is disposed.

  A damping mechanism 22 including a spring 20 and a viscous damper 21 that connect the chimney 2 and the chimney support frame 3 is disposed between the horizontal members 8, 9, 10, 11 of each stage and the chimney 2. The spring constant of the spring 20 and the damping coefficient of the viscous damper 21 are adjusted as shown in Table 2 below.

  The shearing force at the base of the boiler equipment 43 was 38416 kN before the countermeasure was taken and was 25872 kN after the countermeasure was taken. Therefore, the chimney 2 is supported by the chimney support structure 12 arranged on the lowermost horizontal member 7 of the chimney support frame 3, and the spring 20 and the viscous damper 21 are arranged at the positions as described above, respectively. And the natural frequency of the entire chimney composed of the chimney support frame 3 and the natural frequency of the boiler support frame 1 are synchronized, or the damping mechanism 22 and the second damping mechanism function as an energy absorbing vibrator, The shearing force at the base of the equipment 43 is reduced, and the earthquake resistance of the boiler equipment 43 is improved.

  Below, the boiler equipment which concerns on the 3rd Example of this invention is demonstrated concretely using figures. The boiler equipment which concerns on 3rd Example changes the arrangement position of the chimney support structure in the boiler equipment which concerns on 1st Example mentioned above according to the length of the chimney, and has the same structure as this boiler equipment. Have. Since the boiler can, the boiler support frame, the chimney, and the structure of the chimney support frame have the same structure as the boiler equipment according to the first embodiment, the same members are denoted by the same reference numerals and the description thereof is omitted.

  FIG. 11 is a schematic view of boiler equipment according to the third embodiment of the present invention.

  In the boiler facility according to the third embodiment of the present invention, as shown in FIG. 11, the chimney 2 is supported by a chimney support structure 12 disposed on the uppermost horizontal member 11. Between the boiler can (not shown) and the boiler support frame 1, a second damping mechanism including a spring 20 and a viscous damper 21 connecting the boiler can and the boiler support frame 1 is disposed.

  A damping mechanism 22 including a spring 20 and a viscous damper 21 that connect the chimney 2 and the chimney support frame 3 is disposed between the horizontal members 7, 8, 9, 10 of each stage and the chimney 2. The spring constant of the spring 20 and the damping coefficient of the viscous damper 21 are adjusted as shown in Table 3 below.

  The shearing force at the base of the boiler facility 45 was 38416 kN before the countermeasure was taken, and 26578 kN after the countermeasure was taken. Therefore, the chimney 2 is supported by the chimney support structure 12 arranged on the uppermost horizontal member 11 of the chimney support frame 3, and the spring 20 and the viscous damper 21 are arranged at the positions as described above, respectively. And the natural frequency of the entire chimney composed of the chimney support frame 3 and the natural frequency of the boiler support frame 1 are synchronized, or the damping mechanism 22 and the second damping mechanism function as an energy absorbing vibrator, The shearing force at the base of the equipment 45 is reduced, and the earthquake resistance of the boiler equipment 45 is improved.

  Below, the boiler equipment which concerns on the 4th Example of this invention is demonstrated concretely using figures. In the boiler facility according to the fourth embodiment, the ratio of the arrangement height a of the chimney support structure and the chimney length b in the boiler facility according to the first embodiment described above is the same, and the chimney length is increased. It has the same structure as this boiler equipment. Since the boiler can, the boiler support frame, the chimney, and the structure of the chimney support frame have the same structure as the boiler equipment according to the first embodiment, the same members are denoted by the same reference numerals and the description thereof is omitted.

  FIG. 12 is a schematic view of boiler equipment according to the fourth embodiment of the present invention.

In the boiler facility according to the fourth embodiment of the present invention, as shown in FIG. 12, the chimney support frame 3 has three horizontal members 5 in the vertical direction, and the chimney 2 is a central stage in the chimney support frame 3. It is supported by the chimney support structure 12 disposed on the horizontal member 5 (second stage from the bottom). The height H _{2 of the} chimney is 25 m.

  The shearing force at the base of the boiler equipment 47 was 36084 kN before the countermeasure was taken, and was 36005 kN after the countermeasure was taken. Therefore, by supporting the chimney 2 with the chimney support structure 12 disposed on the horizontal member 5 at the center of the chimney support frame 3, the shearing force at the base of the boiler equipment 47 is reduced, and the earthquake resistance of the boiler equipment 47 is improves.

  Below, the boiler equipment which concerns on the 5th Example of this invention is demonstrated concretely using figures. In the boiler facility according to the fifth embodiment, the chimney length is increased by making the ratio between the arrangement height a and the chimney length b of the chimney support structure in the boiler facility according to the first embodiment described above the same. It has the same structure as this boiler equipment. Since the boiler can, the boiler support frame, the chimney, and the structure of the chimney support frame have the same structure as the boiler equipment according to the fourth embodiment, the same members are denoted by the same reference numerals and the description thereof is omitted.

  FIG. 13 is a schematic view of boiler equipment according to the fifth embodiment of the present invention.

In the boiler facility according to the fifth embodiment of the present invention, as shown in FIG. 13, the chimney support frame 12 has nine horizontal members 5 in the vertical direction, and the chimney 2 is the central stage in the chimney support frame 3. It is supported by the horizontal member 5 (the fifth stage from the bottom). The height H ₃ of the chimney 2 is 100 m.

  The shearing force at the base of the boiler equipment 49 was 34555 kN before the countermeasure was taken, and 32017 kN after the countermeasure was taken. Therefore, by supporting the chimney 2 with the chimney support structure 12 disposed on the horizontal member 5 at the center of the chimney support frame 3, the shearing force at the base of the boiler equipment 49 is reduced, and the earthquake resistance of the boiler equipment 49 is improves.

It is the schematic of the boiler equipment which concerns on one Embodiment of this invention. It is a side view of an example of the chimney support structure used for the boiler equipment concerning one embodiment of the present invention. It is the III-III arrow sectional drawing in FIG. It is a top view of the state which installed the damping mechanism in one Embodiment of the chimney support frame used for the boiler equipment which concerns on one Embodiment of this invention. It is a top view of the state which installed the damping mechanism in other embodiment of the chimney support frame used for the boiler equipment which concerns on one Embodiment of this invention. It is a side view which shows other embodiment of the chimney support structure used for the boiler equipment which is one Embodiment of this invention. The further another embodiment of the chimney support structure used for the boiler equipment which is one Embodiment of this invention is shown, (a) is the plane, (b) is the side view. It is the schematic of the boiler installation which concerns on 1st Example of this invention. It is a perspective view of the boiler support frame used for the boiler equipment which concerns on 1st Example of this invention. It is the schematic of the boiler installation which concerns on the 2nd Example of this invention. It is the schematic of the boiler installation which concerns on the 3rd Example of this invention. It is the schematic of the boiler installation which concerns on the 4th Example of this invention. It is the schematic of the boiler installation which concerns on the 5th Example of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Boiler support frame 2 Chimney 3 Chimney support frame 4 Vertical material 5 Horizontal material 6 Diagonal material 7 Bottom level horizontal material 8 Second level horizontal material 9 Third level horizontal material 10 Fourth level horizontal material 11 Top level Horizontal material 12 Chimney support structure 13 Upper ring flange 14 Lower ring flange 15 Rib 16 Bolt 17 Nut 20 Spring 21 Viscous damper 23 Boiler equipment

Claims (8)

A boiler can, a boiler support frame that suspends and supports the boiler can, a chimney disposed on an upper portion of the boiler support frame, and a chimney support frame that supports the chimney ,
A flange is provided on the outer periphery of the chimney, the shaft is passed through the flange from the chimney support frame side, a gap is provided between the flange and a stopper is provided on the shaft, and the chimney is attached to the chimney support frame. A boiler facility characterized by being supported so as to be swingable . The boiler equipment according to claim 1 , wherein the shaft is a bolt and the stopper is a nut. The boiler equipment according to claim 1 or 2 , wherein a damping mechanism is interposed between the chimney and the chimney support frame. The boiler equipment according to claim 3 , wherein a second damping mechanism is interposed between the boiler can and the boiler support frame. The boiler equipment according to claim 3 or 4 , wherein each of the damping mechanism and the second damping mechanism includes a second elastic member and a damping damper arranged in parallel. The boiler equipment according to claim 5 , wherein the damping damper is a viscous damper. Boiler equipment according to any of claims 3 to 6, characterized in that a said damping mechanism the chimney position different from a position swingably supported by the chimney support Frames. Boiler equipment according to any of claims 3 to 6, characterized in that the chimney is arranged the damping mechanism in the position farthest from the position swingably supported by the chimney support Frames.

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