KR101814416B1 - Tilt-up seismic retrofit structure for building - Google Patents

Abstract

The present invention relates to a tilt-up seismic reinforcement structure of an inner wall, capable of enhancing seismic performance. According to the present invention, the structure comprises: a pre-casted concrete reinforcement wall closely coupled to an inner wall of a building or coupled to replace the inner wall in an inner space of the building; and at least one fixation member installed on a side surface of the reinforcement wall and inserted from the side surface of the reinforcement wall towards an adjacent inner wall adjacent to the inner wall to integrate the reinforcement wall and the inner wall. The reinforcement wall includes a bracket buried inside to be extended along the side surface of the reinforcement wall and to be exposed to the side surface. The fixation member is inserted into and fixated to the inner wall through the bracket and an outer end part of the fixation member is supported to the bracket. The bracket includes: an exposure plate exposed to the outside of the reinforcement wall and having a through-hole into which the fixation member is inserted; a buried plate extended towards the inside of the reinforcement wall to be buried in the reinforcement wall from the exposure plate; and a protection housing coupled to the buried plate and the exposure plate to surround the through-hole in order to allow a part where the through-hole is formed to be exposed inside the reinforcement wall.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a tilt-

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a tilt-up inner-wall combined seismic reinforcing structure, and more particularly, to an anti-seismic reinforcing structure for enhancing seismic performance by providing a tilt- .

As the frequency and size of earthquakes have increased in recent years, seismic regulations have been strengthened in Korea, and seismic retrofitting of existing structures is required.

Especially, it is demanded to strengthen the existing school building according to this trend, and since the school building is the living space of the students, more attention should be paid to the earthquake-proof reinforcement works.

In addition, in other business buildings, remodeling works are being widely carried out in order to save the cost and time required to dismantle an existing building and construct a new building.

In addition, the seismic design method is designed to take additional seismic loads into account when designing the structure. In Korea, it was newly built in 1986 and applied to structures larger than a certain scale newly built in 1988 or later. Therefore, seismic design is often not applied to structures before 1988 or low-rise apartments of five stories or less even if they were built after 1988. In addition, in 2005, a mandatory stipulation for compulsory seismic design was introduced for structures with three or more floors. Therefore, if remodeling is required, it is necessary to perform seismic strengthening.

On the other hand, conventional seismic retrofitting techniques include registered patent publications No. 1319527, No. 1670553, No. 0994179, and the like.

In the case of Japanese Patent Registration No. 1319527, since a new wall to be coupled to the outer wall is to be laid by making a form directly on the site, the construction period is long, so that there is a problem that a considerable limitation is imposed on the utilization of the existing building.

In addition, in the case of Japanese Patent Publication No. 1670553, a tilt-up method is used, although it is significant in that a prefabricated reinforced wall made of precast concrete is merely joined to an outer wall of an existing building in the field, The inner wall of the existing building is formed by the coupling structure of the bolt and the nut. However, since the portion where the nut is tightened is simply a concrete wall, there is a problem that the coupling structure can not be firmly formed.

In addition, since Patent Document No. 0994179 relates to an anti-seismic reinforcing structure using a cushioning structure capable of effectively damping and damping the hydraulic force generated in a wall of an existing building, there is an advantage that it is easy to install, And the wall of the existing building is poor, there is a problem that it is difficult to perform seismic strengthening only with the cushioning structure.

In addition, since all of the previously-filed patents are designed to provide an inner steel wall for reinforcement on the outer wall of a building, the seismic-strengthening wall coupled to the outer wall of the building is not sufficient for supporting the local portion such as the inner wall There is a problem in that it is not easy to be applied to an earthquake-proof reinforcement.

Patent Registration No. 1319527 Patent Registration No. 1670553 Patent Registration No. 0994179

An object of the present invention is to provide an earthquake-proof reinforcement structure in which a reinforced wall of a tilt-up type using precast concrete is firmly coupled to an inner wall of an existing building.

In addition, the present invention provides an earthquake-proof reinforcement structure that can further reinforce the rigidity of a local part such as an inner wall of a building using precast concrete.

According to another aspect of the present invention, there is provided a seismic retrofitting structure for a tilt-up inner wall coupled structure, comprising: a precast concrete reinforcing wall coupled to an inner wall of a building in an inner space of the building to closely contact or replace the inner wall; And a fixing member having at least one side surface of the reinforcing wall and inserted in a direction of an adjacent inner wall adjacent to the inner wall at a side of the reinforcing wall to connect the reinforcing wall and the inner wall so as to be integrated, Wherein the fixing member is fixed to the inner wall by being inserted through the bracket and the outer end of the fixing member is fixed to the bracket by being inserted through the bracket, Wherein the bracket is provided with an exposure plate having a through hole through which the fixing member is inserted and exposed to the outside of the reinforcing wall body; A buried plate extending inward of the reinforcing wall so as to be embedded in the reinforcing wall in the exposed plate; And a protective housing coupled to the buried plate and the exposed plate so as to surround the through hole so that a portion where the through hole is formed is exposed in an inner direction of the reinforced wall body.

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The present invention can provide an earthquake-proof reinforcement structure in which a reinforced wall using precast concrete is firmly coupled to an inner wall of an existing building.

Further, the present invention can remarkably complement the joining rigidity of the reinforced wall using the precast concrete in addition to the simple structure.

1 is a perspective view showing a structure of a general building,
FIG. 2 is a perspective view showing a shape having a tilt-up inner wall combined seismic reinforcing structure on the inner wall of a building according to an embodiment of the present invention,
3 is a perspective view illustrating a bracket used in a tilt-up inner wall joined seismic reinforcing structure according to an embodiment of the present invention,
4A to 4D are reference views for explaining mounting of a fixing member (set anchor) according to an embodiment of the present invention,
5 is a perspective view illustrating a tilt-up inner wall joined seismic reinforcing structure according to an embodiment of the present invention,
6 is a perspective view illustrating a tilt-up inner wall combined seismic reinforcing structure according to another embodiment of the present invention,
7 is a perspective view illustrating a tilt-up inner wall combined seismic reinforcing structure according to another embodiment of the present invention,
8A to 8D are flowcharts illustrating a tilt-up inner wall combined seismic retrofitting method according to an embodiment of the present invention.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventive concept. Other embodiments falling within the scope of the inventive concept may readily be suggested, but are also considered to be within the scope of the present invention.

In the following description, the same reference numerals are used to designate the same components in the same reference numerals in the drawings.

Referring to FIG. 1, a building 10, in particular a school building, a school building is illustrated as an example of a building 10 for the sake of convenience in the following description - a foundation 12 is formed below the ground And a building body 11 is formed on the foundation 12. [ In FIG. 1, the 'C' portion is formed by omitting the outer wall 11 and the upper wall of the building for convenience of explanation.

The base 12 generally has a horizontal plane extending from the outer periphery of the building body 11 as a base for stably maintaining the building body 11. [

The building body 11 is formed with outer walls 13 on its outer surface (front, side and rear), a classroom 14 with a window 14a on the front and a corridor 15 . The inner space 17 is divided by the inner wall 16 for partitioning the classroom 14 and the hallway 15 or each classroom 14.

The earthquake-proof reinforcement remodeling of the corridor school building 10 may be performed by a reinforced wall which is coupled to an inner wall or an outer wall, and a front wall outer wall, a partition wall, or a rear wall outer wall, B direction), the seismic strengthening can be achieved by further joining the reinforced wall to the outer surface of the seat surface crossing the front and rear, the outer wall of the partition or the right side.

Hereinafter, a structure and a method of performing seismic strengthening by the reinforcing wall body 110 coupled to the inner wall 16 of the building 10 will be described.

2 to 5, an anti-seismic reinforcing structure according to an embodiment of the present invention includes a reinforcing wall body 110 coupled to an inner wall 16 of the building 10 to be located in an inner space 17 of the building 10, The side wall of the reinforcing wall body 110 is connected to another adjacent inner wall 20 by means of the bracket 120 so that the reinforcing wall body 110 and the reinforcing wall body 110 are in contact with each other, As shown in FIG.

In the case where the reinforcing wall body 110 replaces the inner wall 16, in the case where the conventional inner wall 16 is a coarse structure in which bricks are piled up, or a paved wall using plywood or the like, the conventional inner wall 16 supports It is a case that the conventional inner wall 16 is removed and only the reinforced wall 110 is left.

The other adjacent inner wall 20, that is, the adjacent inner wall 20, is connected to the interlayer wall 21, 22, the building outer wall 24 or the classroom 14 and the corridor 15 in the lower or upper part of the inner wall 16, A partition 23 for partitioning the inner wall, pillars on the left and right of the inner wall, and the like.

Hereinafter, for the sake of convenience, the wall on which the reinforced wall 110 is supported is referred to as the inner wall 16 and the inner wall 16 adjacent to the inner wall 16 adjacent to the inner wall 16, The partition wall 23 partitioning the walls 21 and 22, the building outer wall 24 or the classroom 14 and the corridor 15 and the reinforced wall body 110 installed earlier are referred to as an adjacent inner wall 20.

A bracket 120 supported by a reinforced wall 110 and being embedded in a reinforced wall 110 is formed on an inner wall 16 partitioning the classroom 14 by exemplifying an anti- Is fixed to the interlayer walls 19-19a, 19b by using the fixing member 130. FIG. Of course, the present invention is not limited to this, and the reinforcing wall body 110 may be coupled to the inner wall 16, which divides the classroom 14 and the hallway 15 from the inside of the building 10, So that seismic reinforcement can be achieved.

The reinforced wall 110 may be a precast concrete structure. The reinforced wall 110 is formed in advance in the inner space 17 of the building 10 by a tilt-up method to the inner wall 16 of the building, can do. Of course, the present invention is not limited thereto, and the reinforced wall 110 may be manufactured at a place other than the construction site, and may be moved to the site and then joined by a tilt-up method.

Precast Concrete Structures can be made simply by making molds on the floor according to the required shape, placing reinforcing bars, pouring concrete and curing. Also, the necessary internal structures can be easily buried if they are placed in the mold before the concrete is poured.

The reinforced wall 110 according to the present embodiment has a bracket 120 embedded therein so as to comply with the rigidity of the reinforced wall 110 and to firmly engage with the inner wall 16 of the building. The bracket 120 may be embedded in the interior of the reinforced wall 110 by being positioned inside the formwork in the process of forming the precast concrete reinforced wall 110. The bracket 120 is provided with a plurality of through holes 121a in consideration of the position where the fixing member 130 is inserted when the reinforcing wall body 110 is closely attached to the inner wall 16 and joined to the adjacent inner wall 20. [ . The bracket 120 may be connected to a reinforcing bar (not shown) to be inserted into the reinforcing wall body 110.

The bracket 120 includes an exposure plate 121 having a through hole 121a exposed to the outside of the reinforced wall 110 and through which the fixing member 130 is inserted and the reinforcing wall 110 (Not shown) to extend inwardly of the reinforcing wall 110 so as to be embedded in the reinforcing wall 110.

The exposed plate 121 is exposed to the side surface of the reinforced wall 110 and is brought into close contact with the adjacent inner wall 20 of the building 10 from which the reinforced wall 110 is raised or leaned. One end of the fixing member 130 is fixed to the anchor hole 20a formed in the adjacent inner wall 20 and the other end is coupled to the exposed plate 121 so that the reinforced wall body 110 is fixed to the inner wall 16 And can be tightly coupled to the adjacent inner wall 20 while being firmly supported.

The embedding plate 123 is extended from the exposure plate 121 so as to be embedded in the reinforcing wall body 110 while being firmly connected to the exposure plate 121. The brackets 120 are firmly fixed to the reinforcing wall body 110 . The buried plate 123 may be provided in a plate shape extending in at least one of a longitudinal direction 123a and a width direction 123b of the exposure plate 121, And may be provided with two mutually crossing plates.

The buried plate 123 may be exposed through the interior of the protective housing 125 without being partially buried in the reinforced wall 110 by the coupling of the protective housing 125 structure described below. The exposed portion may be provided with a lifting insertion hole 123c through which the reinforcing wall 110 is inserted. The insertion hole 123c may be formed by inserting a fork or other mobile device when the reinforced wall 110 is moved using the equipment such as a forklift (not shown) in the inner space 17 of the building 10 .

The exposed plate 121 and the buried plate 123 may be made of a rigid material such as steel, stainless steel, stainless steel, or plastic.

The exposing plate 121 may be formed in a long plate shape along the side surface of the reinforcing wall body 110 and the buried plate 123 may be formed in various shapes such as a triangular shape, a square shape, As shown in FIG. The bonding between the various members, such as welding, bonding using an adhesive, or screw bonding, may be utilized.

Further, the bracket 120 may have a shape that surrounds the through hole 121a such that a portion where the through hole 121a is provided is exposed from the inside of the reinforcing wall body 110, And a protective housing (125) coupled thereto.

In this embodiment, the bracket 120 is partly embedded in the reinforcing wall 110 and is firmly fixed (buried plate) 123 and the other part is exposed to the side (exposed plate 121) . In order to insert the fixing member 130 into the through hole 121a of the exposure plate 121, the exposed plate 121 must be exposed to the side surface of the reinforcing wall 110, A structure should be formed in which both sides are exposed.

Therefore, in the present embodiment, in the process of placing the bracket 120 in the inside of the fins, the opposite side of the side where the exposure plate 121 is exposed, as well as the through hole 121a, A protective housing 125 is provided to protect it from being poured.

The protective housing 125 includes an inlet sill plate 125a extending in a direction substantially perpendicular to the exposing plate 121 and coupled to the exposing plate 121 and the landing plate 123, And a cover plate 125b that interconnects the upper portions of the bottom plate 125a and is coupled to the landing plate 123 at one side. Of course, the present invention is not limited thereto, and any structure can be utilized as long as it covers the through hole 121a in a concrete pouring process so that the through hole 121a is not buried.

Since the portion of the reinforcing wall 110 covered with the protective housing 125 is exposed to the outside and the fixing member 130 exposed through the through hole 121a can be fixed to the bracket 120, The rim of the reinforcement wall 125 may be exposed to the surface of the reinforced wall 110. Therefore, the concrete may not be filled into the protective housing 125 when the concrete for forming the reinforced wall 110 is poured.

The protective housing 125 may be made of a rigid material such as steel, stainless steel, stainless steel, or plastic, and may be provided in a plate or plate shape.

The protective housing 125 may be coupled to the exposure plate 121 and the buried plate 123 in such a structure that plates having various shapes such as a triangular shape, a square shape, a round shape, and the like surround the through holes 121a. The bonding between the various members, such as welding, bonding using an adhesive, or screw bonding, may be utilized.

The fixing member 130 is a member that tightly connects the reinforcing wall body 110 and the adjacent inner wall 20 so that the reinforcing wall body 110 closely attached to the building inner wall 16 can move integrally with the building inner walls 16, Anchor, and the like. As long as the fixing member 130 is a member for tightly connecting at least two members, various known means can be used. In the present embodiment, a set anchor will be described as an example for convenience of explanation.

The fixing member 130 includes an anchor bolt 131, an extension sleeve 133 and a fixing nut 135. The fixing member 130 may further include a washer 137 which is fitted inside the fixing nut 135 have.

4A to 4D, an anchor hole 20a is formed in the adjacent inner wall 20 adjacent to the inner wall 16 of the building 10 to which the reinforcing wall 110 is tightly coupled by a drill 1 or the like (Fig. 4A). After the anchor bolt 131 having the expansion sleeve 133 inserted into the formed anchor hole 20a is inserted (Fig. 4B), the auxiliary member 2 inserted from the outside to the end of the expansion sleeve 133 The expansion sleeve 133 is moved toward the inner end of the anchor bolt 131 and the end of the expansion sleeve 133 is fixed to the anchor bolt 131 by the hammers 3, And the anchor bolt 131 exposed to the outside is inserted into the through hole 121a so that the anchor bolt 131 is inserted into the through hole 121a. The fixing nut 135 is tightly fixed to the bracket 120 by using a wrench 4 or the like on the outer end of the anchor bolt 131 exposed through the through hole 121a The combination is done so that the mounting of the set of anchor 130. The The reinforced wall 110 can be firmly fixed to the adjacent inner wall 20 in a state of being closely attached to the inner wall 13 of the existing building 10.

Although the anchoring bolt 131 is fixed to the anchor hole 20a and the reinforcing wall body 110 is coupled to the anchor hole 20a for the sake of convenience of explanation, only the anchor hole 20a is formed in the adjacent inner wall 20, The anchor bolt 131 may be inserted through the through hole 121a after the wall body 110 is moved to the engagement position.

The tilt-up inner wall combined seismic reinforcing structure according to one embodiment includes a precast concrete reinforced wall 110 which is tightly coupled to the inner wall 16 of the building by a tilt-up method. The reinforcing wall 110 and the inner wall 16 can be tightly coupled to each other by tightly coupling the reinforcing wall 110 to the adjacent inner wall 20 by a fixing member 130 such as a set anchor.

The reinforcing wall 110 has a bracket 120 extending along the longitudinal direction to a side of the reinforcing wall 110 so that a part of the reinforcing wall 110 is buried and a part of the reinforcing wall 110 is exposed. Lt; RTI ID = 0.0 > 120 < / RTI > The outer end of the fixing member 130 inserted through the through hole 121a of the bracket 120 and the bracket 120 around the through hole 121a can be exposed to the outside, 125).

After the reinforcing wall body 110 is coupled to the adjacent inner wall 20 by the fixing member 130, the inner space of the housing 125 is filled with cement, mortar, A filling member (not shown) such as a cap can be filled.

Meanwhile, referring to FIG. 5, the bracket 120 according to an embodiment of the present invention may include a spike 123d.

In other words, the spike 123d may be provided on the buried plate 123 of the bracket 120 in order to compensate the draw rigidity of the bracket 120 buried in the precast concrete reinforced wall 110. The spike 123d may have a shape in which the buried plate 123 is partly cut and bent in the outward direction or a shape in which a plate piece of a small size is attached to the buried plate 123 by welding or the like.

If the spike 123d is provided in the landfill 123, the concrete of the spike 123d and the reinforcing wall 110 forms an additional coupling force, so that the drawn rigidity can be improved.

6 is a cross-sectional view illustrating a tilt-up inner wall combined seismic reinforcing structure according to another embodiment of the present invention.

Referring to FIG. 6, the tilt-up inner wall joined seismic reinforcing structure according to another embodiment of the present invention is basically the same as the tilt-up inner wall joined seismic reinforcing structure according to the embodiment described with reference to FIGS.

However, in order to compensate the pulling rigidity of the bracket 120 to be embedded in the precast concrete reinforced wall 110, the buried plate 123 of the bracket 120 is partially cut, And can be provided with a bending removal preventing blade 124a. According to the vanes 124a, the concrete of the vanes 124a and the reinforcing wall 110 forms an additional coupling force, and the pulling rigidity of the bracket 120 can be improved.

7 is a cross-sectional view illustrating a tilt-up inner wall combined seismic reinforcing structure according to another embodiment of the present invention.

Referring to FIG. 7, the tilt-up inner wall joined seismic reinforcing structure according to another embodiment of the present invention is basically the same as the tilt-up inner wall joined seismic reinforcing structure according to the embodiment described with reference to FIGS.

However, in order to compensate the shear failure of the bracket 120 embedded in the precast concrete reinforced wall 110, the buried plate 123 of the bracket 120 is partially cut to expose the exposed plate 121 and the buried plate 123 And a shear reinforcement vane 124b that is bent perpendicularly to both of the shear reinforcement vane 124a and the shear reinforcement vane 124b. According to the wing 124b, the concrete of the wing 124b and the reinforcing wall 110 forms additional bonding force, and the shear fracture of the bracket 120 can be compensated.

8A to 8E are flowcharts illustrating a tilt-up inner wall combined seismic retrofitting method according to an embodiment of the present invention.

Referring to FIG. 8A, a precast concrete reinforced concrete wall 110, which extends along a side surface and is embedded in a side surface of a side of the concrete pipe, is embedded with a bracket 120 having a through- . One or more reinforcing walls 110 may be provided depending on the size of the inner wall 16 and the combined structure may include not only the reinforced wall 110 and the inner wall 16 but also the reinforced wall 110 (Not shown).

8b, an anchor hole 20a is formed in the adjacent inner walls 20-21 and 22 adjacent to the inner wall 16 of the building to which the reinforcing wall is to be coupled (the detailed formation structure of the anchor hole 20a is shown in FIG. And fixing the anchor bolt 131 to the anchor hole 20a of the adjacent inner wall 20 (refer to the detailed fixing structure of the anchor bolt 131) 4b and 4c). In the present embodiment, a structure in which two reinforcing walls 110 are provided in the upper and lower portions will be described as an example. The bottom wall of the reinforced wall 110 is formed by using a bottom plate 21 as an adjacent inner wall 20, The ceiling plate 22 is used as the adjacent inner wall 20. An anchor hole 20a is formed in both the bottom plate 21 and the top plate 22 and the anchor bolt 131 is fixed. When the inner wall 16 of the building is replaced with the reinforcing wall 110, the inner wall 16 of the building is removed and the reinforcing wall 110 is installed at the removed position, An anchor hole 20a can be formed.

8C, the reinforcing wall body 110 is closely contacted with the inner wall 16 so that the fixing member 130, more specifically, the anchor bolt 131 is fitted into the through hole 121a of the bracket 120 And moving to the lower or upper portion of the inner wall 21. The movement of the reinforcing wall body 110 can be performed by moving and installing the lower part first using a crane or the like and then placing the upper reinforcing wall body 110 on the lower reinforcing wall body 110.

Referring to FIG. 8D, the fixing member 130, and more particularly, the step of fixing the outer end of the anchor bolt 131 to be supported by the bracket 120 may be included. That is, the outer end of the anchor bolt 131 can be fixed to be supported by the bracket 120 by using the fixing nut 135 and / or the washer 137 (the anchor bolt 131 is fixed to the fixing nut 135 The detailed fastening structure and method are shown in FIG.

Lastly, the space formed by the housing 125 for exposing the anchor bolts 131 and the fixing nuts 135 that are inserted into the through holes 121a through the outside of the reinforced wall 100 is filled with cement, mortar, etc. A filling member (not shown)

8A to 8E have been described with reference to the reinforced wall 110 according to the embodiment shown in FIG. 5, but the reinforced wall 110 according to the embodiment shown in FIGS. Construction can be done.

8A to 8D, the anchoring bolt 131 is fixed to the anchor hole 20a and then the reinforcing wall body 110 is coupled with the anchor bolt 131. However, only the anchor hole 20a is formed in the adjacent inner wall 21 And the anchoring bolts 131 may be inserted and fixed through the through holes 121a after the reinforced wall 110 is moved to the engagement position.

As described above, according to the joining structure of the building inner wall 16 of the reinforcing wall 100 according to the embodiment of the present invention, the inner wall 16 of the existing building and the reinforcing wall 110 can be integrally moved, .

The present invention has been described in detail above with reference to the embodiments of the present invention. Although the description has been made on the basis of the remodeling of the apartment house for the convenience of explanation, it is obvious to those skilled in the art that the present invention can also be applied to other commercial buildings other than the apartment house.

10: School buildings
16: inner wall
110: reinforced wall
120: Bracket
130: Fixing member

Claims (12)

A precast concrete reinforced wall which is tightly coupled to the inner wall of the building or is substituted to replace the inner wall in an inner space of the building;
And a fixing member having at least one side surface of the reinforcing wall and inserted from the side surface of the reinforcing wall toward the adjacent inner wall adjacent to the inner wall to connect the reinforcing wall and the inner wall so as to be integrated,
Wherein the reinforcing wall includes a bracket extending along the side surface of the reinforcing wall and being buried in the side surface,
The fixing member is inserted through the bracket and fixed to the adjacent inner wall,
An outer end of the fixing member is supported by the bracket,
Wherein the bracket includes: an exposure plate having a through hole through which the fixing member is inserted and exposed to the outside of the reinforcing wall; A buried plate extending inward of the reinforcing wall so as to be embedded in the reinforcing wall in the exposed plate; And a protection housing coupled to the buried plate and the exposed plate so as to surround the through hole so that a portion where the through hole is formed is exposed in an inner direction of the reinforced wall body. delete delete The method according to claim 1,
And the rim of the protective housing is exposed to the front surface or the rear surface of the reinforcing wall. The method according to claim 1,
Wherein the embedding plate is a plate extending in at least one of a longitudinal direction and a width direction of the exposure plate. The method according to claim 1,
Wherein the embedding plate is provided with at least two mutually intersecting plates. delete delete The method according to claim 1,
And a lifting insert hole is provided in a portion of the buried plate exposed and protected by the protective housing. The method according to claim 1,
And the bracket is connected to a reinforcing bar laid on the reinforcing wall. delete delete

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