KR102237239B1 - Seismic Isolation System for building stack - Google Patents

Abstract

The present invention relates to a seismic isolation system for safely protecting a flue from vibration in case of an earthquake and, more specifically, to a prefabricated seismic isolation system for a flue, which is installed on a seismic isolation layer provided in buildings, especially major facilities, to minimize damage caused by earthquakes, to absorb vibration from the earthquake so that a flue connected between floors is not damaged by the earthquake, thereby preventing a high-temperature exhaust gas from leaking from the flue. To this end, a prefabricated seismic isolation system for a flue according to an embodiment of the present invention comprises: a seismic isolation layer flue installed on a seismic isolation layer to connect flues of upper and lower floors; an upper fixing part provided on an upper part of the seismic isolation layer flue to fix the seismic isolation layer flue to the bottom surface of the upper layer; and a lower support part provided on a lower part of the seismic isolation layer flue to support the seismic isolation layer flue so that the same can slide and move.

Description

Seismic Isolation System for building stack

The present invention relates to a seismic isolation system for safely protecting a flue from vibration in the event of an earthquake, and more particularly, it is installed on a seismic isolation layer provided to minimize damage caused by earthquakes to major facilities among buildings, The present invention relates to a prefabricated flue seismic isolation system capable of preventing hot exhaust gas from leaking from the flue by buffering vibrations caused by earthquakes so that the connected flue is not damaged by earthquakes.

In general, in constructing a building, a pipe passing through the floor and the floor is installed.

Such a pipe is damaged by vibration when an earthquake occurs, causing a problem in that gas or liquid passing through the pipe leaks.

In particular, in the case of major facilities among buildings, a seismic isolation layer is provided in preparation for earthquakes.

The seismic isolation layer is provided to minimize damage to the upper layer in which the seismic isolation layer is installed while separating the upper layer and the lower layer on which the seismic isolation layer is provided in a facility, while attenuating the transmission of vibrations from the lower layer to the upper layer when an earthquake occurs.

Such a seismic isolation layer must also be connected through a pipe, and when an earthquake occurs, the pipe located in the seismic isolation layer is twisted, resulting in a problem of being damaged.

In particular, in the case of facilities in which the flue for emergency generators (diesel generators and gas turbine generators) is installed, high-temperature and high-pressure steam is discharged. There is a problem that it becomes difficult to extinguish a fire due to the high-pressure exhaust gas.

In relation to the prior document 1 (Registration Patent 10-1820914 prefabricated common exhaust port for building), a configuration is disclosed in which a part of the main exhaust pipe and the auxiliary exhaust pipe is formed as a bellows type corrugated pipe to provide a buffer function.

However, Prior Document 1 is capable of buffering only within the deformation range of the corrugated pipe, and there is a problem that it is difficult to apply to large flues installed in major facilities.

Prior Document 1 (Registration Patent 10-1820914 Construction assembly-type common exhaust port)

The present invention was conceived to solve the above problem, and when installing a flue in a building or facility, when installing a flue in a seismic isolation layer prepared in preparation for an earthquake, the flue located in the seismic isolation layer divides the bellows pipe shape. The connection part is connected by bolts to the flange so that the flue can be maintained without being damaged by the deformation of the bellows pipe in case of an earthquake, and vibrations caused by earthquakes are generated in the lower part of the flue installed in the seismic isolation layer. As the lower part of the flue slides with the lower layer, the flow range is secured. Even if the flue flows with the bellows pipe in the upper and lower layers of the seismic isolation layer, it is not damaged and remains connected. As the flue is damaged, high-temperature and high-pressure exhaust gas leaks out. The purpose of this is to provide a prefabricated flue seismic isolation system that can prevent secondary accidents from occurring.

The prefabricated flue seismic isolation system according to an embodiment of the present invention for solving the above problems includes a base isolation layer flue 100 installed in a base isolation layer to connect the upper layer and the lower layer flue, and the upper part of the base isolation layer flue 100 The upper fixing part 200 is provided on the bottom surface of the upper layer to fix the seismic isolation layer flue 100 and the lower part supporting the basement isolation layer flue 100 so that the basement isolating layer flue 100 slides and flows. It characterized in that it comprises a support part (300).

Here, the seismic isolation layer flue 100 has a bellows joint 110 formed in the shape of a corrugated pipe and is connected to a plurality of upper and lower layers, and is provided on the upper part of the bellows joint 110, and is connected to the upper layer flue. A plurality of flanges 120 and a lower flange 130 provided under the bellows joint 110 and connecting the lower part of the bellows joint 110 to the lower layer flue and the bellows joint 110 are provided at an end connected to each other. It characterized in that it comprises a joint flange 140 connecting the two bellows joints 110 to each other by bolts.

In this case, the lower support part 300 is provided while surrounding the outer side of the lower flange 130 at a position where the bellows joint 110 is connected to the lower layer, and the support frame 310 supports the lower flange 130, It is characterized in that it comprises a flow support portion 320 provided at each corner of the support frame 310 at the outer lower portion of the support frame 310 to support the bellows joint 110 to slide and flow.

The prefabricated flue seismic isolation system according to an embodiment of the present invention has the following effects.

First, there is an effect of minimizing the transmission of vibration from the lower layer to the upper layer when an earthquake occurs by using the flue installed between the lower layer and the upper layer in the main facility as a bellows pipe.

Second, the lower part of the flue installed in the seismic isolation layer slides when an earthquake occurs and can support the flue, thereby securing a larger flow range and maintaining the flue so that it is not damaged even in a strong earthquake.

Third, the flue of the seismic isolation layer is connected in the form of a bellows tube, but the connection part is connected by a structure in which bolts are fastened to the flange to increase durability and facilitate maintenance.

1 is an overall perspective view of a prefabricated flue seismic isolation system according to an embodiment of the present invention
Figure 2 is a cross-sectional view showing the main portions of the upper fixing portion and the lower support portion in the prefabricated flue seismic isolation system according to an embodiment of the present invention
3 is a plan view showing the lower support of the prefabricated flue seismic isolation system according to an embodiment of the present invention
4 is a cross-sectional perspective view taken along line II of the flow support part in the prefabricated flue seismic isolation system according to an embodiment of the present invention.
Figure 5 is a perspective view showing a state in which insulation means is covered in the prefabricated flue seismic isolation system according to an embodiment of the present invention
6 is a plan view showing a state in which a flow buffer shock absorber is further provided above the flow support part in the prefabricated flue seismic isolation system according to an embodiment of the present invention.

The present invention relates to a flue installed in a seismic isolation layer in case of an earthquake in the case of a main facility in the year installed between the floors and the floors of a facility, and in particular, it is connected by a plurality of bellows pipes, and the upper part is fixedly supported with the upper layer. , The lower part is supported so as to be able to flow in the lower layer, and it is characterized in that it is possible to prevent flue damage by attenuating the transmission of vibration to the upper layer when an earthquake occurs.

Hereinafter, a prefabricated flue seismic isolation system according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is an overall perspective view of a prefabricated flue seismic isolating system according to an embodiment of the present invention, and FIG. 2 is a cross-sectional view showing main portions of an upper fixing part and a lower support part in the prefabricated flue seismic isolating system according to an embodiment of the present invention. .

1 and 2, the present invention is largely installed in the seismic isolation layer to connect the upper layer flue 10 and the lower layer flue 20 in a flowable manner, the seismic isolation layer flue 100, and the seismic isolation layer flue 100 It is configured to include an upper fixing portion 200 fixing the upper layer to the upper layer and a lower support portion 300 supporting the lower portion of the seismic isolation layer flue 100 so as to be flowable in the lower layer.

Here, the seismic insulation layer flue 100 includes a bellows joint 110 in which a plurality is continuously connected between the upper flue 10 and the lower flue 20, and is provided on the top of the bellows joint 110 to provide an upper flue. An upper flange connected to 10, a lower flange 130 provided under the bellows joint 110 and connected to the lower flue 20, and a joint flange 140 connecting a plurality of bellows joints 110 to each other Consists of including.

In the seismic isolation layer flue 100, a plurality of bellows pipes in the form of corrugated pipes are connected to attenuate the flow of the upper layer and the lower layer, and maintain the connection state of the flue even when an earthquake occurs.

At this time, when connecting the bellows joint 110, a flue support bar 150 is further provided to prevent the bellows joint 110 from being deformed during the connection process and making accurate connection difficult.

The flue support bar 150 is fixedly supported so that the upper and lower portions of the bellows joint 110 are not deformed by being installed along the periphery of the outer circumference of the bellows joint 110, and immediately removed when the connection of the bellows joint 110 is completed. Thus, the bellows joint 110 is able to flow.

On the other hand, when the bellows joint 110 of the seismic insulation layer flue 100 is connected to each other, by fastening a plurality of bolts to the joint flange 140, it is possible to maintain a firmly connected state, and maintenance is facilitated.

The upper fixing part 200 is provided in the shape of a square frame on the upper part of the seismic isolation layer flue 100 and a fixing frame 210 for fixing the upper part of the seismic isolation layer flue 100 is provided on the upper layer.

As a result, the upper flue 10 and the upper part of the seismic isolation flue 100 can be stably connected and fixedly supported.

The lower support part 300 connects the lower part of the seismic insulation layer flue 100 and the lower layer flue 20 in a flowable manner.

As a result, a bellows-shaped flue is installed to be able to flow between the upper and lower layers of the seismic isolation layer, so that the flue can be buffered so that the flue is not damaged when an earthquake occurs.

3 is a plan view showing the lower support of the prefabricated flue seismic isolation system according to an embodiment of the present invention.

Referring to FIG. 3, the lower support part 300 supports the lower part of the seismic isolation layer flue 100 so as to be flowable in the lower layer, and a support frame 310 having a rectangular shape along the lower circumference of the base isolation layer flue 100 And, it is configured to include a flow support unit 320 provided at each of the corners of the support frame 310 to support the seismic insulation layer flue 100 to flow.

As a result, the upper part of the seismic isolation layer flue 100 is fixedly supported on the upper layer, but the lower layer is supported so that it can flow, thereby buffering the vibration transmitted from the lower layer when an earthquake occurs, thereby preventing the flue from being damaged.

4 is a cross-sectional perspective view taken along line I-I of the flow support in the prefabricated flue seismic isolation system according to an embodiment of the present invention.

Referring to FIG. 4, the flow support part 320 includes a sliding plate 321 installed below each corner of the support frame 310 to support the lower part of the seismic insulation layer flue 100 so as to slide and flow, and the It is configured to include a sliding frame 322 for supporting the entire lower portion of the sliding plate 321 and a side surface and a portion of the upper circumference slidably.

Here, the sliding plate 321 is formed in a circular plate shape, and the sliding frame 322 is spaced apart at a predetermined interval around the outer circumferential surface of the sliding plate 321, and has a width wider than the entire lower area of the sliding plate 321 The flow hole 322a is formed with a free space on the upper side of the sliding plate 321 and penetrated in a circular shape.

The flow hole 322a supports only a part of the outer circumference from the upper portion of the sliding plate 321 to provide a space through which the sliding plate 321 flows.

At this time, the lower surface of the sliding plate 321 is formed with a bent portion 321a whose central portion is convex downward to reduce friction during flow.

In addition, floor fixing brackets 322b for fixing the sliding frame 322 to the lower layer are provided on both lower sides of the sliding frame 322 so that the sliding frame 322 is rigidly fixed to the lower layer.

On the other hand, the outer surface of the sliding plate 321 and the inner side of the sliding frame 322 are filled with grease so that it can flow while minimizing friction.

For this reason, the seismic isolation layer flue 100 installed in the seismic isolation layer is installed so as to be able to flow with the lower layer where the seismic isolation layer flue 100 is installed by the flow support when an earthquake occurs, and buffers the transmission of vibration from the lower layer when an earthquake occurs, while the upper layer It will be possible to minimize the damage of the.

5 is a perspective view showing a state in which insulation means is covered in the prefabricated flue seismic isolation system according to an embodiment of the present invention.

Referring to FIG. 5, after connecting the seismic insulation layer flue 100 to the upper layer flue 10 and the lower layer flue 20, the external temperature of the flue increases due to the high-temperature and high-pressure steam discharged through the flue. In order to prevent burns of the operator during the occurrence of fire or maintenance due to temperature, the insulation means 400 is wrapped around the outside and covered.

The insulation means 400 is configured to include a bellows side insulation 410 surrounding the outside of the bellows joint 110 and a flange side insulation 420 surrounding the outside of the flange to which the flue is connected.

This insulating means 400 is made in the form of a pad, it is preferable to wrap the outer side of the bellows joint 110 with a glass cross material, and the outer side of the upper flange 120 and the lower flange 130 is to use a cerakwool. desirable.

As a result, heat generated from the high-temperature exhaust gas inside the flue is transferred from the seismic isolation layer to the outside, so that the temperature of the seismic isolation layer itself rises or the risk of fire can be prevented. It is possible to prevent safety accidents caused by heat.

6 is a plan view showing a state in which a flow buffer shock absorber is further provided above the flow support part in the prefabricated flue seismic isolation system according to an embodiment of the present invention.

Referring to FIG. 6, a flow buffer shock absorber is provided on the upper portion of the flow support part 320 in all directions on the outside through which the sliding plate 321 is slid.

The flow buffer shock absorber 330 is installed so that one end of the sliding frame 322 can be rotated vertically, and the other end of the sliding plate 321 is installed so that it can be rotated left and right. When an occurrence occurs, a force to always return to the original position while buffering the sliding plate 321 flows is applied, so that the piping connection state does not change even after the earthquake occurs, and the connection is maintained at the correct position.

This increases the durability of the flue, and effectively responds to vibrations in the event of an earthquake through buffering action.

In the seismic isolation layer for protecting buildings, particularly major facilities from earthquakes, the present invention made as described above enables flow of a certain section using a bellows-type bellows joint in connecting the flue of the upper layer and the lower layer, and seismic isolation. In the lower part of the floor, the flow range is enlarged by the lower layer and the lower support part supporting the flow so that damage to the facility is minimized even in the case of a high-intensity earthquake. It is possible to prevent the occurrence of fire or personal injury due to the leakage of high-temperature and high-pressure exhaust gas due to damage due to vibration.

10: Year of the upper layer 20: Year of the lower layer
100: base insulation layer year 110: bellows joint
120: upper flange 130: lower flange
140: joint flange 150: flue support bar
200: upper fixing part 210: fixing frame
300: lower support part 310: support frame
320: flow support 321: sliding plate
321a: bent portion 322: sliding frame
322a: flow hole 322b: floor fixing bracket
330: flow buffering shock absorber 400: adiabatic means
410: bellows side insulation 420: flange side insulation

Claims (3)

A seismic isolation layer flue 100 installed on the base isolation layer and connecting the flue of the upper layer and the lower layer;
An upper fixing part 200 provided on the top of the seismic isolation layer flue 100 to fix the seismic isolation layer flue 100 on the bottom surface of the upper layer; And
Including; a lower support part 300 provided below the seismic isolation layer flue 100 to support the seismic isolation layer flue 100 to be slid and flowable.
The seismic isolation layer flue 100 has a bellows joint 110 formed in the form of a corrugated pipe and a plurality of them are connected to an upper layer and a lower layer, and an upper flange provided on the upper part of the bellows joint 110 and connected to the upper layer flue ( 120), and a lower flange 130 that is provided under the bellows joint 110 and connects the lower part of the bellows joint 110 to the lower layer flue and the bellows joint 110 is provided at an end connected to each other, and a plurality of bellows Including a joint flange 140 connecting the joint 110 to each other by bolts,
The lower support part 300 is provided while surrounding the outer side of the lower flange 130 at a position where the bellows joint 110 is connected to the lower layer, and the support frame 310 supports the lower flange 130, and the support It is provided at each corner of the support frame 310 at the outer lower portion of the frame 310, and includes a flow support part 320 for supporting the bellows joint 110 to slide and flow,
The flow support part 320 includes a sliding plate 321 and the sliding plate 321 installed below each corner of the support frame 310 to support the lower part of the seismic isolation layer flue 100 so as to slide and flow. It includes a sliding frame 322 slidably supporting the entire lower, side and upper circumference,
The sliding plate 321 is formed in a circular plate shape, and the sliding frame 322 is spaced apart at a predetermined interval around the outer circumferential surface of the sliding plate 321, and has a wider width than the entire area under the sliding plate 321. , The upper side of the sliding plate 321 has a free space and a flow hole 322a penetrated in a circular shape is formed,
The flow hole 322a supports only a part of the outer circumference from the upper portion of the sliding plate 321 to provide a space through which the sliding plate 321 flows,
The lower surface of the sliding plate 321 is formed with a bent portion 321a whose central portion is convex downward so as to reduce friction during flow,
A prefabricated flue seismic isolation system, characterized in that a flow buffer shock absorber 330 is provided on the upper portion of the flow support part 320 in all directions on which the sliding plate 321 slides.
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