KR102628637B1 - Shading structure for seismic shock absorption and noise reduction - Google Patents

Abstract

It consists of an earthquake-resistant pad (10), a base plate (30), a molding frame (40), a pillar (50), a roofing material (60), and a flooring material (70), and a rubber material is placed on the flooring material (70). The seismic pad 10 is installed, the base plate 30 is installed on the seismic pad 10, and an anchor nut 31-1 is formed on the base plate 30 to provide an anchor bolt 31. A sunshade structure in which the pillar 50 is fixed, the molding frame 40 is fixed on the pillar 50, and the roofing material 60 is installed between the molding frame 40 and the molding frame 40. In
The seismic pad 10 is divided into thirds and divided into a first seismic portion (P1), a base portion (B), and a second seismic portion (P2). The first seismic portion (P1) is located on the left side of the base portion (B). ), the second seismic section (P2) is formed on the right side;
The base (B) is formed flat;
The first earthquake-resistant portion (P1) includes a first extension 21, a first protrusion 11, a second extension 22, a second protrusion 12, and a third extension 23. And, the third protrusions 13 are sequentially formed on an inclined surface that decreases from the base B to the left,
The second seismic portion (P2) is symmetrical and has the same shape as the first seismic portion (P1) about the base (B);
The base B, the first protrusion 11, the second protrusion 12, and the third protrusion 13 are all configured at the same height to contact the lower part of the base plate 30;
The installation direction of the seismic pad 10 is the direction in which the first seismic portion P1, the base portion B, and the second seismic portion P2 are sequentially formed (P1-B-P2) and the molding frame 40. ) are installed so that the directions (x) are parallel to each other;
The seismic pad 10 is installed on both the lower side of the base plate 30 of the left pillar 51 and the lower side of the base plate 30 of the right pillar 52. A sunshade structure equipped with a seismic pad, characterized in that as,
The earthquake-resistant pad 10 of the present invention prevents conduction due to earthquakes and vibrations that mainly occur in the direction parallel to the direction (-x, x) of the molding frame 40, and also absorbs deformation due to thermal expansion and thermal contraction. It is designed to provide enhanced earthquake resistance, vibration resistance, and noise resistance.

Description

Shading structure for seismic shock absorption and noise reduction}

The present invention relates to a sunshade structure installed in schools, parking lots, apartment playgrounds, sports facilities, etc., and is a technology for improving the earthquake resistance of the sunshade structure and reducing noise of the sunshade structure.

Generally, sunshade structures are installed in schools, parking lots, apartment playgrounds, sports facilities, etc. Shade structures installed in this way are required to be earthquake resistant and reduce noise generation. The Korean Peninsula is located away from the Pacific Rim seismic zone, so relatively few earthquakes occur compared to plate boundaries. Full-scale earthquake observation in Korea began in 1978, and an average of 35 earthquakes occur per year. Since 1978, 10 earthquakes of magnitude 5.0 or higher have occurred, and earthquakes of magnitude 5 to 6 have occurred before that, including the Jiri Mountain earthquake in 1936 and the Pyongyang earthquake in 1952. With the expansion of the earthquake observation network and the development of earthquake observation technology, the number of earthquakes per year has tended to increase since 1999, so Korea must also prepare measures against earthquakes.

Figure 1 is a prior art, in which the foundation (A) of a reinforced concrete structure, which is the basis of a solar power generation device, is formed on a building or ground floor slab, and a vibration isolation unit 530 is constructed on the foundation (A). In addition, it is a solar power generation device that combines a foundation pad reinforcement structure and a foundation pad and a vibration isolation function to allow the post 510 to be erected on the foundation A through the vibration isolation unit 530, wherein the foundation ( A), after fixing at least one foundation reinforcing bar to the slab reinforcing bar placed for slab construction, pouring and curing the slab concrete with the upper end of the foundation reinforcing bar exposed to form a slab. During construction, four anchor bolts (580) are placed in a vertical position and form a square arrangement around the foundation reinforcing bar exposed at the bottom of the slab, and the four anchor bolts (580) are wrapped around the perimeter. A reinforcing structure consisting of an integrated combination of binding reinforcing bars that are welded together and binds each anchor bolt (580) is placed, and the reinforcing structure is moved back and forth and left and right to meet the basic construction specifications of the solar power generation device. After being placed in position, a plurality of sub-rebars are connected between the reinforcing structure and the foundation reinforcing bars to fix the reinforcing structure, and a square box-shaped frame is placed around the reinforcing structure in the center, Forming a foundation pad by pouring and curing pad concrete with the upper end of the reinforcing structure exposed; The vibration isolation unit 530 includes a center spring member 540 manufactured to have about the diameter of the post 510, a lower plate integrally welded with the center spring member 540 at the lower part of the center spring member 540, and An upper plate that faces the lower plate at the top of the center spring member 540 and is integrally welded with the center spring member 540, and an anchor bolt (580) penetrating the bolt through hole of the lower plate from the lower direction to the upper direction. ) and a first nut that is screwed together to couple the lower plate to the upper surface of the base portion (A), and a bolt that simultaneously penetrates the bolt through hole of the post flange 520 and the bolt through hole of the upper plate from the upper direction to the lower direction. It includes a member and a second nut that is spirally coupled to the bolt member to couple the upper plate to the post flange 520, and the vibration isolation unit 530 is installed between the post 510 and the foundation pad to prevent vibration. transmission can be minimized, and vibration isolation function is provided in response to external forces generated in the vertical or horizontal direction through the vibration isolation unit 530. Vibration is reduced through the vibration isolation unit 530, and at the same time, vibration is reduced through the installation surface or foundation pad. A photovoltaic power generation device incorporating a foundation pad and a vibration-proof function is provided, and a structure for reinforcing the foundation rebar, which is characterized in that the posts 510 are elastically and firmly coupled to each other to ensure stable installation without being separated from each other.

This prior art has a very complex structure, so the work is very difficult and expensive materials must be used.

In addition, with regard to the "clicking" noise generated from the roof of the awning, on days when there is a large difference in daily temperature, the roofing material flows repeatedly, generating interference noise between the roof frame and the roofing material, and this interference is continuous and When repeatedly accumulated, wear occurs in at least one of the roof frame and the roofing material, and over time, it may eventually become damaged and fail to function as a normal roof. In order to solve this problem, shading devices have been proposed that have a leak-proof structure that structurally prevents water from leaking inside by increasing the adhesion between the roof material and the roof frame. However, among the sealing members made of elastic material, the one that prevents water leaks Because the part has a plate shape, there is a problem that the elasticity may weaken and condense over time, and as a result, the adhesion with the roofing material is weakened, resulting in a significant possibility of water leakage. In addition, over time, deformation of the roofing material may occur, and as a result, the surface adhesion between the sealing member and the roofing material weakens, and fine space gaps may occur, so the problem of water leakage cannot be fundamentally solved. Additionally, it has the disadvantage of generating noise due to thermal expansion and contraction of the roof.

As a countermeasure to this problem, the present invention seeks to provide an invention for reducing earthquake resistance, vibration, and noise in structures such as shaded buildings installed in schools, apartment playgrounds, parking lot roofs, and sports facilities.

Prior art 1: Republic of Korea Patent Publication No. 10-2321755 (announcement date, November 4, 2021) (Solar power generation device combining foundation reinforcement structure and foundation pad with dustproof function) Prior art 2: Republic of Korea Patent Publication No. 10-2177944 (announcement date, November 12, 2020) (Assembly structure of column and foundation of Korean-style structure with corrosion resistance and deformation prevention function) Prior art 3: Republic of Korea Patent Publication No. 10-2023-0010328 (publication date, January 19, 2023) (shading device)

First, the purpose of the present invention is to improve the earthquake resistance of sunshade structures.

Second, the purpose of the present invention is to improve the vibration resistance of the sunshade structure.

Third, the purpose of the present invention is to reduce the noise of the awning structure.

It consists of an earthquake-resistant pad (10), a base plate (30), a molding frame (40), a pillar (50), a roofing material (60), and a flooring material (70), and a rubber material is placed on the flooring material (70). The seismic pad 10 is installed, the base plate 30 is installed on the seismic pad 10, and an anchor nut 31-1 is formed on the base plate 30 to provide an anchor bolt 31. A sunshade structure in which the pillar 50 is fixed, the molding frame 40 is fixed on the pillar 50, and the roofing material 60 is installed between the molding frame 40 and the molding frame 40. In

The seismic pad 10 is divided into thirds and divided into a first seismic portion (P1), a base portion (B), and a second seismic portion (P2). The first seismic portion (P1) is located on the left side of the base portion (B). ) The second seismic section (P2) is formed on the right side;

The base (B) is formed flat;

The first earthquake-resistant portion (P1) includes a first extension portion (21), a first protrusion portion (11), a second extension portion (22), a second protrusion portion (12), and a third extension portion (23). And, the third protrusions 13 are sequentially formed on an inclined surface that decreases from the base B to the left,

The second seismic portion (P2) is symmetrically formed in the same shape as the first seismic portion (P1) about the base (B);

The base (B), the first protrusion 11, the second protrusion 12, and the third protrusion 13 are all configured at the same height to contact the lower side of the base plate 30. ;

The installation direction of the seismic pad 10 is the direction in which the first seismic portion P1, the base portion B, and the second seismic portion P2 are sequentially formed (P1-B-P2) and the molding frame 40. ) are installed so that the directions (x) are parallel to each other;

The seismic pad 10 is installed on both the lower side of the base plate 30 of the left pillar 51 and the lower side of the base plate 30 of the right pillar 52. A sunshade structure with a seismic pad installed. This is provided so that the earthquake-resistant pad 10 of the present invention prevents conduction due to earthquakes and vibrations that mainly occur in the direction parallel to the direction (-x, x) of the molding frame 40, and also prevents deformation due to thermal expansion and thermal contraction. It is structured to absorb.

In addition, it further includes a fixing plate 35 below the seismic pad 10, and places the seismic pad 10 on the fixing plate 35 so that the fixing plate 35 and the seismic pad 10 are connected to each other. Fix, place the base plate 30 on the seismic pad 10, and fix the seismic pad 10 and the base plate 30 to each other, and the seismic pad 10 is provided with a fixing plate 35. The fixing nut 36-2 to which the base plate 30 is fixed and the fixing nut 31-2 to which the base plate 30 is fixed are formed separately, and the fixing plate 35 is fixed to the lower part via the seismic pad 10. , the base plates 30 are separately fixed to the upper part of the seismic pad 10, so that most of the vibration of the ground caused by an earthquake is absorbed by the seismic pad 10 and no vibration occurs in the column 50.

First, the present invention has the effect of improving the earthquake resistance of the sunshade structure.

Second, the present invention has the effect of improving the vibration resistance of the sunshade structure.

Third, the present invention has the effect of reducing noise from the awning structure.

Figure 1 Conventional earthquake-resistant structure
Figure 2 Typical shading structure
Figure 3 Shade structure with a general earthquake-resistant pad installed
Figure 4 Example 1 of earthquake-resistant pad for sunshade structure of the present invention
Figure 5 Example 2 of earthquake-resistant pad for sunshade structure of the present invention
Figure 6 Example 3 of earthquake-resistant pad for sunshade structure of the present invention
Figure 7 Example 4 of earthquake-resistant pad for sunshade structure of the present invention
Figure 8 Another embodiment of the sunshade structure installed with the earthquake-resistant pad of the present invention

Hereinafter, only the parts necessary to understand the content of the present invention will be described. Description of other parts is omitted to the extent that it does not confuse the gist of the present invention.

Additionally, terms and words used in this specification and claims were defined by the inventor to aid understanding in the process of explaining his invention.

Figure 2 shows a general sunshade structure, and Figure 3 shows a general sunshade structure with an earthquake-resistant pad installed. This sunshade structure is composed of an earthquake-resistant pad 10, a base plate 30, a molding frame 40, a pillar 50, a roofing material 60, and a flooring material 70, and the flooring material 70 The seismic pad 10 made of rubber is installed on top, the base plate 30 is installed on the seismic pad 10, and an anchor nut 31-1 is formed on the base plate 30 to provide an anchor. The pillar 50 is fixed with a bolt 31, the molding frame 40 is fixed on the pillar 50, and the roofing material 60 is between the molding frame 40 and the molding frame 40. This is the form in which it is installed.

The present invention is shown in more detail in Figure 4 below. Figure 4 is Example 1 of the earthquake-resistant pad of the sunshade structure of the present invention, Figure 5 is Example 2 of the earthquake-resistant pad of the sunshade structure of the present invention, Figure 6 is Example 3 of the earthquake-resistant pad of the sunshade structure of the present invention, and Figure 7 is Example 3 of the earthquake-resistant pad of the sunshade structure of the present invention. Shows Example 4 of the earthquake-resistant pad.

The present invention is composed of a seismic pad 10, a base plate 30, a molding frame 40, a pillar 50, a roofing material 60, and a flooring material 70, and is placed on the flooring material 70. The seismic pad 10 made of rubber is installed, the base plate 30 is installed on the seismic pad 10, and an anchor nut 31-1 is formed on the base plate 30 to provide an anchor bolt. The pillar 50 is fixed with (31), the molding frame 40 is fixed on the pillar 50, and the roofing material 60 is installed between the molding frame 40 and the molding frame 40. In the shading structure,

The seismic pad 10 is divided into thirds and divided into a first seismic portion (P1), a base portion (B), and a second seismic portion (P2). The first seismic portion (P1) is located on the left side of the base portion (B). ) The second seismic section (P2) is formed on the right side;

The base (B) is formed flat;

The first earthquake-resistant portion (P1) includes a first extension 21, a first protrusion 11, a second extension 22, a second protrusion 12, and a third extension 23. And, the third protrusions 13 are sequentially formed on an inclined surface that decreases from the base B to the left,

The second earthquake-resistant portion (P2) is symmetrical and has the same shape as the first earthquake-resistant portion (P1) about the base (B);

The base B, the first protrusion 11, the second protrusion 12, and the third protrusion 13 are all configured at the same height so as to contact the lower part of the base plate 30;

The installation direction of the seismic pad 10 is the direction in which the first seismic portion P1, the base portion B, and the second seismic portion P2 are sequentially formed (P1-B-P2) and the molding frame 40. ) are installed so that the directions (x) are parallel to each other;

The seismic pad 10 is installed on both the lower side of the base plate 30 of the left pillar 51 and the lower side of the base plate 30 of the right pillar 52. A sunshade structure with a seismic pad installed. provides.

Embodiment 1 of the earthquake-resistant sunshade structure pad of the invention shown in FIG. 4 has the first protrusion 11, the second protrusion 12, and the third protrusion 13 having outer surfaces at right angles and inner surfaces inclined. It is formed.

In the second embodiment of the earthquake-resistant sunshade structure pad of the present invention shown in FIG. 5, the first protrusion 11, the second protrusion 12, and the third protrusion 13 are all formed in a “∩” shape. .

In the third embodiment of the earthquake-resistant sunshade structure of the present invention shown in Figure 6, the first protrusion 11, the second protrusion 12, and the third protrusion 13 are all formed as a plurality of protrusions in an embossed form. It is done.

In the fourth embodiment of the earthquake-resistant sunshade structure pad of the present invention shown in Figure 7, the first protrusion 11, the second protrusion 12, and the third protrusion 13 are all formed in an “M” shape. there is. In the drawing, for convenience, only the first protrusion 11 and the second protrusion 12 are shown, and the third protrusion 13 is omitted.

Figure 8 shows another embodiment of the sunshade structure installed with the earthquake-resistant pad of the present invention. FIG. 8(a) is an overall schematic diagram, and FIG. 8(b) shows only the nut formed on the seismic pad 10. The seismic pad 10 is the seismic pad 10 shown in Examples 1 to 4. Applies.

Another embodiment of the present invention shown in FIG. 8 is to insert and secure the earthquake-resistant pad 10 between the base plate 30 and the fixing plate 35.

That is, the seismic pad 10 is separately formed with a fixing nut 36-2 to which the fixing plate 35 is fixed and a fixing nut 31-2 to which the base plate 30 is fixed,

The seismic pad 10 is placed on the fixing plate 35 and fixed to each other, and the base plate 30 is placed on the seismic pad 10 to fix the seismic pad 10 and the base plate 30 to each other.

More specifically, a fixing plate 35 is fixed to the lower part via the seismic pad 10, and a base plate 30 is fixed to the upper part of the seismic pad 10 separately from the seismic pad 10.

First, a fixing nut (36-1) is formed on the fixing plate 35, and a fixing nut (36-2) is formed on the seismic pad 10 to secure the fixing plate 35 and the seismic pad 10 with fixing bolts ( 36) and secure them together.

Next, after placing the base plate 30 on the seismic pad 10, an anchor nut 31-2 is formed on the seismic pad 10, and an anchor nut 31-1 is formed on the base plate 30. Then, the earthquake-resistant pad (10) and the base plate (30) are fixed to each other with anchor bolts (31).

The effects of the present invention thus formed are as follows.

When an earthquake or vibration occurs, the support force is strong in the direction perpendicular to the molding frame 40, that is, in the direction (-y, y) where there are multiple columns 50, so it is difficult to overturn, and the direction of the molding frame 40 ( In the direction parallel to -x, x), the support force is relatively weak and it is easy to fall over.

In addition, on days when there is a large temperature difference in daily temperature, the roofing material 60 repeatedly expands and contracts, generating a "popping" noise, and when this interference accumulates continuously and repeatedly, the molding frame 40 and the roofing material ( 60), at least one of them is worn out, and eventually becomes damaged over time, causing a problem that the roof cannot function as a normal roof.

In addition, when the roofing material 60 thermally expands, the direction (-x, ), the roofing material 60 is relatively shorter than the roof material 60, so expansion does not occur much, and the length is relatively long in the direction parallel to the direction (-x, x) of the molding frame 40. , x), so if there is no means to prevent noise, significant noise is generated from the roofing material 60. Conversely, even when the roofing material 60 undergoes heat shrinkage, the same noise is generated.

As a countermeasure against such earthquakes or thermal expansion, conventional technologies have very complex structures, making the work very difficult and expensive materials must be used.

In the present invention, the seismic pad 10 is installed in a direction parallel to the direction (-x, x) of the molding frame 40, and the first seismic portion (P1), the base portion (B), and the second seismic portion (P2) are The seismic pads 10 formed in this order are installed on the lower part of the base plate 30 in a direction parallel to the direction (-x, x) of the molding frame 40. To be more specific, it is as follows.

On the left pillar 51 side, a seismic pad 10 is installed, in which the first earthquake resistant part P1, the base part B, and the second earthquake resistant part P2 are sequentially formed, so that on the left pillar 51 side, the earthquake resistant pad 10 is installed on the outer part of the roof 60. The first seismic section (P1) and the second seismic section (P2) are located on the inner side,

Since the seismic pad 10 in which the first seismic portion (P1), the base portion (B), and the second seismic portion (P2) are sequentially formed is installed on the right column 52 side, the inner portion of the roof 60 is installed on the right column 52 side. The first seismic section (P1) and the second seismic section (P2) are located on the outer side.

Therefore, if an earthquake or vibration occurs,

When the sunshade structure 100 receives a force that causes it to fall in a direction parallel to the direction (-x, x) of the molding frame 40, that is, toward the left column 51, the earthquake-resistant pad (on the outer side of the left column 51) When the first seismic section (P1) of 10) is stressed and absorbs earthquakes or vibrations, and conversely, when it receives a force that causes it to fall toward the right column (52), the seismic pad (10) on the outer side of the right column (52) is 2The earthquake-resistant area (P2) is stressed and absorbs earthquakes or vibrations.

In addition, when the roofing material 60 undergoes thermal expansion or contraction,

When the roofing material 60 thermally expands, the seismic pad 10 on the left pillar 51 contracts due to pressure on the first seismic portion P1 on the outer side.

Conversely, the seismic pad 10 on the side of the right pillar 52 contracts due to the pressure of the second seismic portion P2 on the outer side.

When the roofing material 60 undergoes heat contraction, in contrast, it contracts under pressure.

By installing the seismic pad 10 formed with the first seismic portion P1 and the second seismic portion P2 capable of absorbing the thermal expansion and contraction of the roofing material 60, noise can be reduced.

Meanwhile, in a normal state without phenomena such as earthquakes, vibrations, thermal expansion, or thermal contraction, the base B serves to stably support the lower side of the base plate 30 of the pillar 50.

Therefore, the earthquake-resistant pad 10 of the present invention prevents conduction due to earthquakes and vibrations that mainly occur in the direction parallel to the direction (-x, x) of the molding frame 40, and also absorbs deformation due to thermal expansion and thermal contraction. It is configured to perform functions with enhanced earthquake resistance, vibration resistance, and noise resistance.

As another embodiment of the present invention, the seismic pad 10 is separately formed with a fixing nut 36-2 to which the fixing plate 35 is fixed and a fixing nut 31-2 to which the base plate 30 is fixed. , the fixing plate 35 is fixed to the lower part via the earthquake-resistant pad 10, and the base plate 30 is separately fixed to the upper part of the earthquake-resistant pad 10, so that it can respond more strongly to earthquake resistance. It works. In other words, most of the vibration of the ground caused by an earthquake is absorbed by the seismic pad 10 and no vibration occurs in the column 50, which has the effect of responding to earthquakes more effectively.

Above, although the present invention has been described with reference to specific embodiments, it may be carried out in other embodiments within the same technical scope, equivalents may be used as substitutes, and the present invention is not limited to the disclosed embodiments.

The present invention is designed to prevent conduction due to earthquakes and vibrations that mainly occur in the direction parallel to the direction (-x, x) of the molding frame 40, and to absorb deformation due to thermal expansion and thermal contraction, Since it is about a structure that can perform enhanced earthquake-resistant, vibration-resistant, and noise-resistant functions, it has industrial applicability.

10 Earthquake-resistant pad 11 First protrusion
12 2nd protrusion 13 3rd protrusion
21 1st extension 22 2nd extension
23 Third extension 30 Base plate
31 Anchor bolt 31-1 Anchor nut
31-2 Anchor nut 35 Fixing plate
36 fixing bolt 36-1 fixing nut
36-2 Fixing nut 40 Molding frame
50 Pillar 51 Left Pillar
52 Right pillar 60 Roof material
70 Flooring 100 Shade structure
A base
B base
P1 1st earthquake-resistant department
P2 2nd earthquake-resistant department

Claims (6)

It consists of an earthquake-resistant pad (10), a base plate (30), a molding frame (40), a pillar (50), a roofing material (60), and a flooring material (70), and a rubber material is placed on the flooring material (70). The seismic pad 10 is installed, the base plate 30 is installed on the seismic pad 10, and an anchor nut 31-1 is formed on the base plate 30 to provide an anchor bolt 31. A sunshade structure in which the pillar 50 is fixed, the molding frame 40 is fixed on the pillar 50, and the roofing material 60 is installed between the molding frame 40 and the molding frame 40. In
The seismic pad 10 is divided into thirds and divided into a first seismic portion (P1), a base portion (B), and a second seismic portion (P2). The first seismic portion (P1) is located on the left side of the base portion (B). ), the second seismic section (P2) is formed on the right side;
The base (B) is formed flat;
The first earthquake-resistant portion (P1) includes a first extension 21, a first protrusion 11, a second extension 22, a second protrusion 12, and a third extension 23. And, the third protrusions 13 are sequentially formed on an inclined surface that decreases from the base B to the left,
The second earthquake-resistant portion (P2) is symmetrical and has the same shape as the first earthquake-resistant portion (P1) about the base (B);
The base (B), the first protrusion 11, the second protrusion 12, and the third protrusion 13 are all configured at the same height to contact the lower side of the base plate 30. ;
The installation direction of the seismic pad 10 is the direction in which the first seismic portion P1, the base portion B, and the second seismic portion P2 are sequentially formed (P1-B-P2) and the molding frame 40. ) are installed so that the directions (x) are parallel to each other;
The seismic pad 10 is installed on both the lower side of the base plate 30 of the left pillar 51 and the lower side of the base plate 30 of the right pillar 52. A sunshade structure equipped with a seismic pad, characterized in that .
The method according to claim 1, wherein the first protrusion (11), the second protrusion (12), and the third protrusion (13) are provided with a seismic pad, characterized in that the outer surface is formed at a right angle and the inner surface is inclined. Shade structure.
The sunshade structure according to claim 1, wherein the first protrusion (11), the second protrusion (12), and the third protrusion (13) are all formed in a “∩” shape.
The sunshade structure equipped with a seismic pad according to claim 1, wherein the first protrusion 11, the second protrusion 12, and the third protrusion 13 are all formed in an embossed form as a plurality of protrusions. .
The sunshade structure according to claim 1, wherein the first protrusion (11), the second protrusion (12), and the third protrusion (13) are all formed in an “M” shape.
According to any one of claims 1 to 5,
It further includes a fixing plate 35 below the earthquake-resistant pad 10,
Place the seismic pad 10 on the fixing plate 35 to fix the fixing plate 35 and the seismic pad 10 to each other,
The base plate 30 is placed on the seismic pad 10, and the seismic pad 10 and the base plate 30 are fixed to each other,
The fixing plate 35 and the seismic pad 10 are secured with fixing bolts through the fixing nut 36-1 formed on the fixing plate 35 and the fixing nut 36-2 formed on the seismic pad 10. They are fastened together with (36);
An anchor bolt connects the seismic pad 10 and the base plate 30 through the anchor nut 31-2 formed on the seismic pad 10 and the anchor nut 31-1 formed on the base plate 30. (31) A sunshade structure equipped with a seismic pad, characterized in that it is formed by fixing it to each other.