KR101821158B1 - Supporting Frame Having Earthquake Proof Construction for Electric and Telecommunication Panel - Google Patents

Abstract

Provided is an earthquake-resistant platform having earthquake-proof performance, capable of withstanding an earthquake force, thereby preventing an electric and telecommunications panel installed thereon from being damaged or improperly operated by the earthquake force. The earthquake-resistant platform comprises: an earthquake-resistant upper plate (1) receiving a weight load of the electric and telecommunications panel installed in an upper portion thereof to transmit the weight load to a lower portion, and withstanding an overturning moment caused by the earthquake force with an internal force; a vertical pipe supporting part (2) welded to a corner of the earthquake-resistant upper plate (1) or the corner and the center of a portion between both corners to transmit the load that the earthquake-resistant upper plate (1) receives to a lower portion; and a base pad part (3) withstanding the weight load of the electric and telecommunications panel and an external force resulting from the earthquake force, and transmitting the weight load and earthquake force to a base of the electric and telecommunications panel.

Description

{Supporting Frame Having Earthquake Proof Construction for Electric and Telecommunication Panel}

More particularly, the present invention relates to an earthquake-resistant band for installing a telecommunication panel having an earthquake-proof performance capable of withstanding a high seismic force, and more particularly to an earthquake- And more particularly to an earthquake-proof band for mounting a telecommunication panel which receives a seismic force with an earthquake-proof performance that can withstand seismic forces, so that the telecommunication panel is not damaged by a seismic force and is not disturbed by operation.

An earthquake is a phenomenon in which the energy inside the earth comes to the surface and the earth is divided and shaken and acts as a load on the building.

The seismic load is the inertial force due to the ground motion, and the building may be horizontal or vertical irregular, or the unexpected action of the non-structural element may cause the load to be concentrated on a specific layer or a specific structural member.

Therefore, all structures subject to the earthquake-proof design and their constituent members should be provided with a certain strength to withstand the earthquake and ductility capable of flexibly responding to the earthquake shake .

Seismic design means a design considering additional earthquake load in designing to maintain the safety and function of the structure even after earthquake or earthquake. However, it is not designed to prevent damage to all expected earthquakes, The following three items are targeted.

 Structural and non-structural members should not be damaged in small-scale earthquakes. In mid-scale earthquakes, damage to non-structural members should not be allowed. Structural members should not be damaged. And should not cause injury to persons.

The requirement for earthquake-resistant design was introduced in 1988, and the earthquake-resistant design obligation was applied to six or more floors or buildings with a floor area of 100,000 or more. In 1995, the building was expanded from more than 6 floors to more than 10,000 floors. It has been expanded to more than 1,000, and by 2015, seismic design has been mandated for all buildings with more than three floors or more than 500.

Generally, telecommunication panels such as switchgear, surveillance panel, distribution panel, and information telecommunication panel are bulky and have a large load, so they are installed on the platform installed on the floor of the building.

Therefore, when an earthquake occurs in a building with such a telecommunication panel, damage to the panel occurs. The magnitude of the seismic force affecting the building in case of an earthquake varies depending on the structural characteristics such as the height, shape and material of the building, It is necessary to protect the panel from earthquakes and the seismic performance of the frame is required to protect the panel.

In particular, in areas where systems are required to be processed online / real-time, such as information and communication panels, especially in areas with high publicity, in our country, which is close to Japan where earthquakes are frequent, There is a desperate need.

Therefore, the earthquake disaster countermeasures law (Law 9636) and the earthquake disaster countermeasures enforcement ordinance (Presidential order 21362) require all earthquake disaster countermeasures law (Law 9636) and earthquake disaster countermeasures enforcement order (Presidential decree 21362) to establish earthquake countermeasures for all public buildings and facilities.

Conventional frame requires seismic frame with maximum seismic performance at minimum production cost by installing panel on general frame without seismic performance.

In case of existing earthquake resistance, the bridge is mainly used for expensive damping and attenuation. Therefore, there is a problem that the earthquake does not occur over a certain scale in Korea.

1. Korean Patent Laid-Open Publication No. 10-2012-0030224 (public date: March 28, 2012) 2. Korean Registered Patent No. 10-1505629 (registered on Mar. 18, 2015) Stands for installing instruments having vibration-proof and dustproof performance 3. Korean Patent Registration No. 10-1341152 (Date of Registration: December 06, 2013) Switchboard with an earthquake-proof device 4. Korean Registered Patent No. 10-1294605 (Registered Date: Aug. 02, 2013) Resistance to earthquake and vibration

In order to solve the above-mentioned problems, the present invention provides an earthquake-proof earthquake-proof earthquake-proof earthquake-proof earthquake-proof earthquake-proof earthquake-proof earthquake- And to provide an earthquake-resistant band for installation in a telecommunication panel.

The earthquake-resistant band of the present invention has an earthquake-proof performance capable of withstanding seismic force so that the electric communication panel installed at the upper end is not damaged by the seismic force and does not interfere with operation, and the electric communication panel is installed on the upper part, An earthquake-resistant upper plate portion which receives the earthquake-induced earthquake, A lower end of the upper end portion of the upper end portion of the upper end portion of the diaphragm upper plate portion is connected to a lower end portion of the upper end portion of the upper end portion of the diaphragm upper end portion, A vertical pipe support base which is made up of a plurality of vertical pipe supports which are hollow and have a pipe shape and a predetermined thickness and an outer diameter; A vertical pipe support for supporting the vertical pipe support, a vertical pipe support for supporting the vertical pipe support, a vertical pipe support for supporting the vertical pipe support, A base pad portion composed of the same number of base pads; A bottom end of the vertical pipe support is welded to the upper portion of the base pad and the upper end of the vertical pipe support is welded to the outer circumferential surface of the vertical pipe support to bracing the vertical pipe support, And a reinforcing ring portion made of the same number of reinforcing rings as the vertical pipe supports.

Wherein the upper and lower horizontal portions, the front vertical portion and the rear vertical portion are formed of an upper portion and a lower portion of the electric communication panel, And two horizontal pipes each having a predetermined thickness to withstand an external force due to seismic force, which are formed by bending a flat plate, welding or drawing, and equidistantly spaced from each other; And the inside of which is made up of the upper horizontal part, the lower horizontal part, the left waterproofing straight part and the right vertical part, is rectangular, and can withstand the external force due to the self weight of the electric communication panel and the seismic force. And is made up of two vertical pipes, each of which has a predetermined thickness and is formed by welding a plate after bending the flat plate or by drawing.

The vertical pipe support is inserted into a predetermined portion of both ends of each of the upper horizontal portion and the lower horizontal portion so that the two ends of the portion of the vertical pipe support, which contact the distal end of the vertical pipe support and the upper horizontal portion and the lower horizontal portion, An insertion hole is formed.

The base pad is a quadrangular plate having a predetermined thickness.

The base pad is formed with a support bar coupling hole through which the vertical pipe support is inserted and welded, and an anchor coupling hole to which an anchor of the foundation of the electric communication panel is coupled.

The reinforcing ring has a cylindrical shape having a predetermined diameter and a height of 40 to 80 mm, and a supporting frame coupling hollow is formed in the center of the reinforcing ring, into which the vertical pipe support is inserted.

Wherein the vertical pipe support and the horizontal upper horizontal portion have a first welding portion for joining, the first welding portion reduces the height of the earthquake-proof band, and increases the member force, which is a force generated inside the vertical pipe support and the horizontal upper portion, The lower circumference of the insertion hole and the upper periphery of the upper end of the vertical pipe support are welded to each other so that the welded portion is not formed on the upper portion of the upper horizontal portion.

The vertical pipe support and the horizontal lower horizontal portion have a second weld portion for joining and the second weld portion welds the edge of the joint portion by fillet welding to increase the force of the vertical pipe support and the horizontal lower horizontal portion, And a length of 10 to 20 mm.

Wherein the reinforcing ring and the vertical pipe support have a third weld for joining and the third weld welds the rim of the joint by fillet welding to increase the shear resistance of the vertical support pipe support, To 20 mm.

The reinforcing ring and the base pad have a fourth welding portion. The fourth welding portion welds the rim of the welding portion by fillet welding to increase the shearing resistance of the reinforcing ring, and the leg length of the welding portion is 10 to 15 mm .

Wherein the base pad and the vertical pipe support have a fifth weld for engagement and the fifth weld has a lower circumference of the support attachment hole and a lower end of the vertical pipe support to increase the force of force between the base pad and the lower end of the vertical pipe support. And then welded to the lower portion of the base pad so as to prevent the welding flesh from rising.

The problem to be solved by the present invention can be solved with the earthquake resistance described above.

According to the earthquake-resistant band for mounting a telecommunication panel according to the present invention, since the cross-sectional reinforcement is applied to the both end portions having a large shear force acting on the column structure, the shear resistance ability can be improved, and the welding length of both end- The resistance is improved, so that the structure is simple and the manufacturing cost is low.

Fig. 1 is a perspective view of an entire assembled perspective view according to an earthquake-proof band for installation of a telecommunication panel according to the present invention,
Fig. 2 is an exploded perspective view of an earthquake resistant band for installation of a telecommunication panel according to the present invention,
FIG. 3 is a schematic view of an entire assembly according to an earthquake-resistant band for installation of a telecommunication panel according to the present invention,
Fig. 4 is a perspective view showing the earthquake-resistant portion of the present invention,
Fig. 5 is an enlarged view of a portion A showing a welded portion for joining the respective components according to the earthquake-proof band for installation of a telecommunication panel under the seismic force of the present invention
6 is a perspective view of an earthquake-resistant top plate according to an earthquake-proof band for installation of a telecommunication panel according to the present invention,
7 is a schematic view of an earthquake-resistant top plate according to an earthquake-resistant band for installation of a telecommunication panel according to the present invention,
8 is a perspective view and a schematic view of a vertical pipe support according to an earthquake-proof band for installation of a telecommunication panel according to the present invention,
9 is a perspective view of a reinforcing ring according to an earthquake resistant band for installation of a telecommunication panel according to the present invention,
10 is a schematic view of a reinforcement ring according to an earthquake-resistant band for installation of a telecommunication panel according to the present invention,
11 is a perspective view of a base pad according to an earthquake-resistant band for installation of a telecommunication panel according to the present invention,
12 is a schematic view of a base pad according to an earthquake-resistant band for installation of a telecommunication panel according to the present invention,

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS First, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

The term " earthquake-resistant portion for telecommunication panel mounting subjected to seismic force "in accordance with the present invention is defined by the term " The present invention is not limited to these embodiments.

Hereinafter, a preferred embodiment of the "earthquake-resistant band for installation of telecommunication panels subjected to seismic force" according to the present invention will be described in detail.

The following examples are merely illustrative of the present invention and are not intended to limit the scope of the present invention.

2 is an exploded perspective view of an earthquake resistant band for installation of a telecommunication panel according to an embodiment of the present invention. Fig. 3 is an exploded perspective view of the earthquake resistant band for installation of a telecommunication panel according to the present invention. 4 is a perspective view in which a telecommunication panel is installed on the earthquake-resistant portion of the earthquake-proof power of the present invention, FIG. 5 is a perspective view of an earthquake-resistant portion for installation of a telecommunication panel according to the present invention, 6 is a perspective view of an earthquake-resistant top plate according to an earthquake-resistant band for installation of a telecommunication panel according to the present invention, and Fig. 7 is a perspective view showing an earthquake- FIG. 8 is a schematic view of an earthquake-proof upper plate according to an earthquake-proof band for installation of a telecommunication panel, FIG. 9 is a perspective view of a reinforcing ring according to an earthquake resistant band for installation of a telecommunication panel according to the present invention, and FIG. 10 is a perspective view of a vibration pipe for installing a telecommunication panel FIG. 11 is a perspective view of a base pad according to an earthquake-resistant band for installation of a telecommunication panel according to the present invention, and FIG. 12 is a schematic view of a base pad according to an earthquake-

As shown in Figs. 1 to 3, the earthquake-resistant band A of the present invention has an earthquake-proof performance capable of withstanding seismic forces so that the electric communication panel installed at the upper end is not damaged by a seismic force or interfered with operation.

The earthquake-resistant band (A) comprises an earthquake-resistant upper plate part (1) installed on the upper part of the earthquake-resistant zone, receiving the weight of the electric communication panel and transmitting it to the lower part, and receiving the earthquake- The upper end portion of the upper end portion of the upper diaphragm 1 is connected to the lower end of the upper end portion of the upper diaphragm 1 by welding to the lower end of the upper end portion of the upper end portion of the upper diaphragm 1, A vertical pipe supporting part 2 composed of a plurality of vertical pipe supports 21 which are resistant to the increase of the member force in the reverse direction, which is generated in the inside of the object, and which are hollow and have a predetermined thickness and an outer diameter; And is welded to the lower end of the vertical pipe support (21). The vertical pipe support (21) is welded to the vertical pipe support (21) A base pad portion 3 composed of the same number of base pads 31 as the support base 21; The lower end of the vertical pipe support 21 is welded to the upper portion of the base pad 31. The upper end of the vertical pipe support 21 is welded to the outer peripheral surface of the vertical pipe support 21, And a reinforcing ring portion (4) formed of a reinforcing ring (41) in the same number as that of the vertical pipe support for enhancing shear stress by increasing the section modulus of the lower portion by acting as a bracing.

In the present invention, the bottom portion of the vertical pipe support 21, which has the largest shear force due to the conduction moment, is reinforced by the reinforcing ring 41 to increase the section modulus, And the vertical pipe support 21 has two welding portions on the upper seismic isolation upper plate portion 1 to increase the welding length as a whole to increase the bonding force, so that the performance against the conduction moment is improved The structure of the frame is simple, the seismic performance is excellent, and the structure is simple, which is advantageous in that the production cost is low.

FIG. 4 is a view showing an example in which the earthquake-resistant band A of the present invention is installed on a concrete foundation of an electric communication panel and the earthquake-resistant band A is combined with the electric communication panel frame to install the electric communication panel. (A) according to the present invention, which is easy to install and easy to construct, and has a low production cost suitable for application to general buildings, in addition to a place where damage may occur when a problem occurs.

As shown in FIG. 5, the vertical pipe support 21 and the horizontal upper horizontal portion 111 have a first welding portion 5 for coupling.

The first welding portion 5 may be inserted into the support hole insertion hole 1111 in order to reduce the height of the earthquake-resistant band A and to increase the force, which is a force generated in the vertical pipe support 21 and the horizontal upper horizontal portion 111, And welded to the upper part of the horizontal upper part 111, so as not to be welded to the upper part of the horizontal upper part 111.

The vertical pipe support 21 and the horizontal lower horizontal portion 112 have a second weld 6 for joining.

The second welded portion 6 is welded to the edge of the jointed portion by fillet welding to increase the force of the vertical pipe support 21 and the horizontal lower portion 112 and the leg length of the welded portion is formed to be 10 to 20 mm .

The reinforcing ring (41) and the vertical pipe support (21) have a third weld (7) for engagement.

The third welded portion 7 is welded to the edge of the jointed portion by fillet welding in order to increase the shear resistance of the vertical pipe support 21, and the leg length of the welded portion is 10 to 20 mm.

The reinforcing ring 41 and the base pad 31 have a fourth welding portion 8 for bonding.

In order to increase the shear resistance of the reinforcing ring 41, the fourth welding portion 8 is welded to the edge of the joint by fillet welding, and the leg length of the welding is 10 to 15 mm.

The base pad 31 and the vertical pipe support 21 have a fifth weld 9 for engagement.

The fifth welding portion 9 may be formed in a lower circumferential direction of the support pipe coupling hole 311 and a lower circumferential groove of the lower pipe support 21 in order to increase the force between the base pad 31 and the lower end of the vertical pipe support 21. [ So as to prevent welding flesh to the bottom of the base pad 31.

Since the seismic resistance upper plate portion 1 and each of the vertical pipe supports 21 have two portions of the first welding portion and the second welding portion, the welding length is increased and the bonding strength is increased.

Each of the vertical pipe supports 21 has the third welding portion and the fifth welding portion, so that the welding length is increased and the bonding strength is increased.

Also, since the section modulus of the lower portion of the vertical pipe support 21 is increased by the reinforcing ring 41, the shear stress is increased, thereby improving seismic performance.

6 and 7, the earthquake-proof upper plate part 1 is installed on the upper part of the earthquake-proof upper plate part 1, receives the weight of the electric communication panel and transmits it to the lower part, The horizontal upper horizontal portion 111 and the horizontal lower horizontal portion 112 are formed in a rectangular shape having a notch having a front vertical portion 113 and a rear vertical portion 114. The horizontal upper horizontal portion 111, The horizontal portion 112 and the front vertical portion 113 and the rear vertical portion 114 have a predetermined thickness to withstand the external force due to the self weight and seismic force of the electric communication panel, Two horizontal pipes (11) which are made by drawing and installed so as to be equidistantly spaced from each other; The two horizontal transverse pipes 11 are welded to each other at both ends and welded to each other with a vertical upper horizontal portion 121, a vertical lower horizontal portion 122, a left waterproof vertical portion 123 and a right vertical portion 124 (12) having a rectangular cross section and having a predetermined thickness so as to withstand the external force due to the self weight and seismic force of the electric communication panel, .

The vertical pipe support 21 is inserted into a predetermined portion of each of the horizontal upper horizontal portion 111 and the horizontal lower horizontal portion 112 so that the end of the vertical pipe support 21 and the horizontal upper horizontal portion 111 And a portion where the lower horizontal portion 112 and the lower horizontal portion 112 are welded to each other.

As shown in Fig. 8, the vertical pipe support portion 2 is welded to the corner portion of the upper seismic isolation upper plate portion 1, or between the corner portion and the two corner portions to weld the seismic isolation upper plate portion 1 A plurality of vertical pipes having a hollow shape and having a predetermined thickness and an outer diameter of a predetermined length, the vertical force of which is generated by the seismic force and the vertical force generated in the inside of the object, And a support base 21.

In a typical electrical telecommunication panel, the vertical pipe support part (2) is provided only at the corner part and consists of four vertical pipe support parts (21). In the wide electric telecommunication panel, the vertical pipe support part (2) In the electric communication panel having a deep depth and a wide width, the vertical pipe support part 2 has a corner part and a center part of the width and the depth, Four of them are installed, so a total of eight may be installed.

9 and 10, the lower end of the reinforcing ring portion 4 is welded to the upper portion of the base pad 31, and the upper end of the vertical pipe support 21 passes through the vertical pipe support 21 and serves as a bracing member for the vertical pipe support 21 to improve the shear stress by increasing the section modulus of the lower portion. The reinforcing ring 41 has the same number as the vertical pipe support.

The lower section modulus refers to the lower portion of the earthquake-resistant band A and refers to the lower portion of the vertical pipe support 21 and the portion where the reinforcing ring 41 is installed.

The reinforcing ring 41 has a cylindrical shape having a predetermined diameter and a height of 40 to 80 mm and is formed with a support base coupling hollow 411 through which the vertical pipe support 21 is inserted and welded.

The reinforcing ring 41 may be made of a hollow filled steel material or a hollow steel material.

As shown in FIGS. 11 and 12, the base pad 31 withstands an external force due to the self weight and seismic force of the electric communication panel, and transmits the self weight and seismic force of the electric communication panel to the base of the electric communication panel And a base pad 31 welded to the lower end of the vertical pipe support 21 and of the same number as the vertical pipe support 21.

The base pad 31 is a quadrangular plate having a predetermined thickness.

The base pad 31 is formed with a support base coupling hole 311 through which the vertical pipe support 21 is inserted and welded and an anchor coupling hole 312 through which an anchor of the foundation of the electric communication panel is formed do.

According to the earthquake-resistant band for mounting a telecommunication panel according to the present invention, since the cross-sectional reinforcement is applied to the both end portions having a large shear force acting on the column structure, the shear resistance ability can be improved, and the welding length of both end- The resistance is improved, so that the structure is simple and the manufacturing cost is low.

A: Earthquake resistance vs. 1:
11: Horizontal pipe 111: Horizontal upper horizontal part
1111: support base insertion hole 112: horizontal lower part horizontal part
1121: support base insertion hole 113: front vertical portion
114: rear vertical portion 12: vertical vertical pipe
121: vertical upper horizontal part 122: vertical lower horizontal part
123: Left waterproofing portion 124: Right vertical portion
2: vertical pipe support rod 21: vertical pipe support
3: base pad part 31: base pad
311: Supporting fitting hole 312: Anchor fitting hole
4: reinforcing ring portion 41: reinforcing ring
411: support bracket coupling hollow 5: first welded portion
6: second welding part 7: third welding part
8: fourth welding part 9: fifth welding part

Claims (3)

(A) having an earthquake-resistant performance capable of withstanding seismic forces so that a telecommunication panel installed at the upper end is not damaged by a seismic force,
The earthquake-resistant band (A) comprises an earthquake-resistant upper plate part (1) installed on the upper part of the earthquake-resistant zone, receiving the weight of the electric communication panel and transmitting it to the lower part, and receiving the earthquake-
The upper end portion of the upper end portion of the upper diaphragm 1 is connected to the lower end of the upper end portion of the upper diaphragm 1 by welding to the lower end of the upper end portion of the upper end portion of the upper diaphragm 1, A vertical pipe supporting part 2 consisting of a plurality of vertical pipe supports 21 which are resistant to the increase in the force of the member, which is a reverse force generated in the inside of the object, and which are hollow and have a predetermined thickness and an outer diameter;
And is welded to the lower end of the vertical pipe support (21). The vertical pipe support (21) is welded to the vertical pipe support (21) A base pad portion 3 composed of the same number of base pads 31 as the support base 21;
The lower end of the vertical pipe support 21 is welded to the upper portion of the base pad 31. The upper end of the vertical pipe support 21 is welded to the outer peripheral surface of the vertical pipe support 21, And a reinforcing ring portion (4) made of the same number of reinforcing rings (41) as the vertical pipe supports to improve the shear stress by increasing the section modulus of the lower portion by acting as bracing,
The seismic isolation upper plate 1 includes a horizontal upper horizontal portion 111 and a horizontal lower horizontal portion 112. The interior of the upper vertical portion 114 is formed by a front vertical portion 113 and a rear vertical portion 114, The vertical part 114 and the vertical lower part 112 and the front vertical part 113 and the rear vertical part 114 have a predetermined thickness so as to withstand the external force due to the self weight and seismic force of the electric communication panel, Two horizontal tubes 11, which are formed by welding after being bent or drawn, and installed so as to be equidistantly spaced from each other;
The inside of each of the two transverse pipes 11 is welded to each other and welded to each other. The inside of the transverse pipe is composed of a vertical upper horizontal portion 121, a vertical lower horizontal portion 122, a left waterproofing straight portion 123, It is composed of two vertical pipes (12) which have a square cross section and have a certain thickness so as to withstand the external force due to the self weight and seismic force of the electric communication panel, And,
The vertical pipe support 21 is inserted into a predetermined portion of each of the horizontal upper horizontal portion 111 and the horizontal lower horizontal portion 112 so that the end of the vertical pipe support 21 and the horizontal upper horizontal portion 111 And the lower horizontal portion 112 are welded to each other at two positions, and the support base insertion holes 1111 and 1121 are formed,
The base pad 31 is a quadrangular plate having a predetermined thickness,
The base pad 31 is formed with a support base coupling hole 311 through which the vertical pipe support 21 is inserted and welded and an anchor coupling hole 312 through which the foundation anchor of the electric communication panel is coupled ,
The reinforcing ring 41 has a cylindrical shape having a predetermined diameter and a height of 40 to 80 mm and is formed with a support base coupling hollow 411 into which the vertical pipe support 21 is inserted,
The vertical pipe support 21 and the horizontal upper horizontal portion 111 have a first welding portion 5 for coupling,
The first welding portion 5 may be inserted into the support hole insertion hole 1111 in order to reduce the height of the earthquake-resistant band A and to increase the force, which is a force generated in the vertical pipe support 21 and the horizontal upper horizontal portion 111, And the outer peripheral portion of the upper end of the vertical pipe support 21 is welded and welded to the upper portion of the horizontal upper horizontal portion 111,
The vertical pipe support 21 and the horizontal lower horizontal portion 112 have a second weld 6 for joining,
The second welding portion 6 welds the rim of the joint portion by fillet welding to increase the force of the vertical pipe support 21 and the horizontal lower portion 112 and the leg length of the weld is formed to be 10 to 20 mm ,
The reinforcing ring (41) and the vertical pipe support (21) have a third weld (7) for engagement,
The third welded portion 7 is formed by welding a rim of the jointed portion by fillet welding to increase the shear resistance of the vertical pipe support 21 and having a leg length of 10 to 20 mm,
The reinforcing ring 41 and the base pad 31 have a fourth weld portion 8 for engagement,
In order to increase the shear resistance of the reinforcing ring 41, the fourth welding portion 8 is welded to the edge of the joint portion by fillet welding, the leg length of the welding is 10 to 15 mm,
The base pad 31 and the vertical pipe support 21 have a fifth weld 9 for engagement,
The fifth welding portion 9 may be formed in a lower circumferential direction of the support pipe coupling hole 311 and a lower circumferential groove of the lower pipe support 21 in order to increase the force between the base pad 31 and the lower end of the vertical pipe support 21. [ Welded to the lower surface of the base pad (31) so as to prevent the welded portion from being welded to the lower portion of the base pad (31). The earthquake-
delete delete

Images