CN113062623A

CN113062623A - Reinforcing structure for uneven joints of outer vertical surfaces of concrete frame structures

Info

Publication number: CN113062623A
Application number: CN202110296104.1A
Authority: CN
Inventors: 郭瑞顺; 柳青海; 杨雪洁
Original assignee: MMI Planning and Engineering Institute IX Co Ltd
Current assignee: MMI Planning and Engineering Institute IX Co Ltd
Priority date: 2021-03-19
Filing date: 2021-03-19
Publication date: 2021-07-02
Anticipated expiration: 2041-03-19
Also published as: CN113062623B

Abstract

The invention provides a reinforcing structure for uneven nodes on outer vertical surfaces of a concrete frame structure, belongs to the technical field of frame reinforcement, and aims to solve the problems that when the existing reinforcing structure for uneven nodes of the concrete frame structure is used, the fixing effect cannot be automatically enhanced when an earthquake occurs, and the existing reinforcing structure cannot be connected with a cross rod in an auxiliary mode. The invention relates to a reinforcing structure for uneven joints of outer facades of a concrete frame structure, which comprises a main body, a cross beam and a stress piece; the main part is the rectangular long strip structure of concrete material, and the embedding is installed inside the mounting groove of crossbeam, and the atress piece is installed in the main part outside, is connected with the atress groove through the inserted block, and what make the atress piece can stabilize is connected fixedly with the main part, and the inside that makes the connecting plate can insert the mounting groove is fixed by the connecting piece, and this device can be firm to be installed, when meetting earthquake, and the atress piece can be to the inside removal of mounting groove, and then makes the atress piece can contact fixity, and then automatic reinforcing fixed effect.

Description

Reinforcing structure for uneven joints of outer vertical surfaces of concrete frame structures

Technical Field

The invention belongs to the technical field of frame reinforcement, and particularly relates to a reinforcement structure for uneven joints of outer vertical surfaces of a concrete frame structure.

Background

Reinforced concrete frame structures are one of the most common forms of building structure in industrial and civil construction, where the nodes serve to distribute internal forces, coordinate member deformation, and maintain structural integrity in a structural load bearing system. Under the action of earthquake, the frame nodes are easy to shear and damage in the core area, the outer facade nodes are easy to shear, and the reinforcing structure is needed.

The prior art discloses a reinforcing method and a reinforcing structure for a concrete frame structure with uneven outer vertical surfaces, wherein the reinforcing method comprises the steps of digging a main channel on a concrete protective layer of a node core area, wherein the node core area is an area where beams and columns are intersected; drilling holes on the peripheral beams; installing UHPC precast slabs on the peripheral beams, matching preset extension channels on the UHPC precast slabs with the main channels to form channels, corresponding to the through holes and the holes preset on the UHPC precast slabs, and matching to form a pore channel; installing a fiber composite batten in the channel; and installing an anchoring piece, inserting the implantation limb of the anchoring piece into the channel, and installing the overlapping limb of the anchoring piece in the channel. The invention provides a reinforcing method and a reinforcing structure, which solve the problem that the concrete frame node seismic strengthening method and the concrete frame node seismic strengthening structure in the prior art are not high in practicability when used under the condition that the beam columns of the uneven-joint nodes on the outer vertical surfaces are not equal in width.

However, the reinforcing structure of the uneven nodes of the existing concrete frame structure cannot be automatically reinforced and fixed when in use, cannot automatically reinforce the fixing effect when encountering an earthquake, cannot be assisted and connected with a cross rod, and cannot be clamped and fixed and cannot be effectively spliced and reinforced and fixed when the reinforcing structure of the uneven nodes of the existing concrete frame structure is used without a clamping position.

Disclosure of Invention

The invention aims to provide a reinforcing structure for uneven nodes on outer vertical surfaces of a concrete frame structure, and aims to solve the problems that the existing reinforcing structure for uneven nodes of the concrete frame structure cannot be automatically reinforced and fixed, cannot automatically reinforce and fix the effect and cannot be connected with a cross rod in an earthquake, and the existing reinforcing structure for uneven nodes of the concrete frame structure has no clamping position and cannot be clamped and fixed and cannot be effectively spliced and reinforced and fixed in the use process.

The purpose of the invention is realized by the following technical scheme:

a reinforcing structure for uneven joints of outer vertical surfaces of a concrete frame structure comprises a main body, a cross beam, stress pieces, connecting pieces, a fixing plate, a control plate and reinforcing pieces;

the main body is of a rectangular strip structure and is embedded in the mounting groove of the beam; the stress piece is arranged on the outer side of the main body; the connecting piece is inserted into the fixing groove of the cross beam and is positioned in the middle of the outer side of the connecting plate; the fixed plate is arranged at the front end of the cross beam; the top of the control plate is inserted into the rectangular groove of the stress piece, the bottom of the control plate is inserted into the inner groove of the fixed plate, and the rectangular plate is inserted and installed in the control groove of the control plate; the reinforcing member is sleeved at the front end of the cross beam, the control panel is embedded in a rectangular groove in the reinforcing groove of the reinforcing member, and the fixture blocks of the reinforcing member are inserted in the rectangular grooves on the two sides of the cross beam;

the stress piece is of a U-shaped plate structure, two sides of the upper end and the lower end of the stress piece are of wedge structures, two insertion blocks are arranged on two sides inside the stress piece, an insertion rod is arranged in the middle of the stress piece, a rectangular groove is arranged in the middle of the inner side of the bottom of the stress piece, the stress piece is installed on the outer side of the main body, the insertion blocks are inserted into the two stress grooves of the main body, and the insertion rods are inserted into the insertion grooves;

the fixed plate is of a rectangular plate-shaped structure, I-shaped limiting grooves are formed in the bottoms of the two ends of the fixed plate, an inner groove is formed above the inner portion of the fixed plate, two rectangular plates are arranged inside the inner groove, two springs are mounted, the outer side of the top end of the inner groove is of an inclined structure, the front end of a connecting piece is arranged in the limiting grooves, and T-shaped blocks are further mounted in the limiting grooves.

Further, the main part is the concrete material, including setting up in the slot of atress tank bottom intermediate position, the both sides of slot are the slope column structure, and the bottom of slot is the arc structure, and atress groove (101) are L shape structure, and two atress grooves set up in the both sides of main part.

Further, the crossbeam is L shape structure, and its inside front end is equipped with the mounting groove, and the top both sides of mounting groove are the slope column structure, and inside both sides bottom is equipped with the fixed slot, and the fixed slot is the rectangle structure, and the both sides bottom of crossbeam is equipped with two rectangular channels, and the rectangular channel is in the both sides bottom of mounting groove.

Further, the inserted block is L-shaped structure, the bottom is inclined-shaped structure, the bottom of the inserted rod is arc-shaped structure, the connecting plate is U-shaped plate-shaped structure and is arranged at the bottom of two sides of the stress element, and the connecting plate is inserted into two sides of the mounting groove.

Furthermore, the connecting piece is including the draw-in groove, and it is the rectangle structure, and the connecting piece is U-shaped plate column structure, and its both ends outside is equipped with the T-shaped piece, and inside both sides are equipped with two draw-in grooves.

Furthermore, the fixed plate further comprises a pressing plate arranged inside the inner groove and in a rectangular plate-shaped structure, two rectangular grooves are formed in the side edges of the pressing plate, the pressing plate is arranged inside the inner groove, and the bottom of the pressing plate is in contact with the top end of the spring.

Further, the control plate is of a rectangular plate-shaped structure, two control grooves are formed in the inner side of the bottom of the control plate, and the control grooves are of a rectangular plate-shaped structure.

Further, the reinforcement is L shape plate-shaped structure, and its both sides are the slope column structure, and inside is equipped with the reinforcement groove, and the reinforcement groove is T shape structure, and the top inboard in reinforcement groove is equipped with the rectangular channel, and both sides are equipped with two fixture blocks, and the fixture block is the rectangle structure.

Compared with the prior art, the invention has the beneficial effects that:

1. in the device, a stress piece is arranged and is used for being arranged outside a main body and then is connected with a stress groove through an insertion block, so that the stress piece can be stably connected and fixed with the main body, the main body can be firstly provided with the stress piece before being arranged with a cross beam, then is connected with the cross beam, a connecting plate can be inserted into the inside of the installation groove and fixed by a connecting piece, the device can be stably arranged, when the device meets an earthquake, the main body moves and simultaneously drives the stress piece to move together, so that the stress piece can move towards the inside of the installation groove, the stress piece can be contacted and fixed, the fixing effect is automatically enhanced, the insertion block is used for being inserted into the inside of the stress groove and then is stably connected with the main body, the main body can drive the stress piece to move together to buffer the impact force, the insertion rod is used for being inserted into the inside of the insertion groove and further assisting in fixed installation, the stress piece can not move up and down, the connecting plate is used for being inserted into the mounting groove, and the connecting piece can be embedded into the outer side of the connecting plate when being mounted, so that the stress piece and the main body can be in auxiliary connection with the cross beam;

2. in the device, a fixing plate is arranged, after the connecting piece is installed, the front end of the connecting piece can be inserted into the limiting groove, the control panel can be inserted into the inner groove, the spring can support the control panel to move upwards, the top end of the spring can be inserted into the rectangular groove of the stress piece, the device can be stably clamped and installed, the device cannot be loose, and can be stably and fixedly installed, the limiting groove plays a role in installing the front end of the connecting piece and a T-shaped block, the connecting piece can be stably installed and used, and further the stress piece and the cross beam are assisted to be fixed and cannot be separated, the inner groove is used for installing a pressing plate through the spring, the pressing plate can receive the power of the spring to move, the pressing plate can be upwards pushed after the bottom end of the control panel is inserted, and further the top end of the control panel can be inserted into the groove of the stress piece, the control panel can assist in limiting and fixing by the aid of the contact.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

FIG. 1 is a schematic perspective view of a reinforcement structure for a concrete framing structure incorporating the present invention;

FIG. 2 is a schematic bottom view of the reinforcement structure for concrete framing structure facade unevenness joint of the present invention;

FIG. 3 is an exploded perspective view of the reinforcement structure for the out-of-plane uneven joint of the concrete frame structure of the present invention;

FIG. 4 is an exploded rear view and partially enlarged structural view of the reinforcement structure for concrete framing structure facade unevenness nodes of the present invention;

FIG. 5 is a schematic perspective view of the main body of the reinforcement structure for concrete framing structure facade unevenness node of the present invention;

FIG. 6 is a schematic perspective view of a stressed member of the present invention for use in a reinforcement structure for a concrete frame structure having a node with uneven vertical outer surfaces;

FIG. 7 is a schematic bottom view of the connector assembly of the present invention for use in reinforcing structures for concrete framing structure out-of-plane uneven joints;

FIG. 8 is a perspective view of a control panel for the reinforcing structure for concrete framing structure facade unevenness joint according to the present invention;

in the figure, 1, a main body 2, a cross beam 3, a stress element 4, a connecting element 5, a fixing plate 6, a control plate 7, a reinforcing member 101, a stress groove 102, a slot 201, a mounting groove 202, a fixing groove 301, an insert block 302, an insert rod 303, a connecting plate 401, a clamping groove 501, a limiting groove 502, an inner groove 503, a pressure plate 601, a control groove 701, a reinforcing groove 702 and a clamping block.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples. It is to be understood that the specific embodiments described herein are merely illustrative of the invention and are not limiting of the invention. It should be further noted that, for the convenience of description, only some of the structures related to the present invention are shown in the drawings, not all of the structures.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures. Meanwhile, in the description of the present invention, the terms "first", "second", and the like are used only for distinguishing the description, and are not to be construed as indicating or implying relative importance.

Examples

As shown in fig. 1 to 8, the reinforcing structure for the uneven-facade joints of the concrete frame structure comprises a main body 1, a cross beam 2, a stress element 3, a connecting element 4, a fixing plate 5, a control plate 6 and a reinforcing element 7.

The main part 1 is rectangular long strip-shaped structure, is made of concrete material, and is embedded in the mounting groove 201 of the beam 2 in the main part 1. The connecting piece 4 is inserted into the fixing groove 202 of the cross beam 2 and is arranged at the middle position outside the connecting plate 303 of the force-bearing piece 3. The top of the control plate 6 is inserted into the rectangular groove of the force receiving member 3, the bottom is inserted into the inner groove 502 of the fixing plate 5, and the rectangular plate is inserted into the control groove 601 of the control plate 6. The reinforcing member 7 is sleeved at the front end of the cross beam 2, the control plate 6 is embedded in the rectangular groove inside the reinforcing groove 701 of the reinforcing member 7, and the clamping blocks 702 of the reinforcing member 7 are inserted into the rectangular grooves on the two sides of the cross beam 2.

The stress element 3 is of a U-shaped plate structure, two sides of the upper end and the lower end of the stress element are of wedge-shaped structures, two insertion blocks 301 are arranged on two sides of the interior of the stress element 3, an insertion rod 302 is arranged in the middle of the interior of the stress element, and a rectangular groove is formed in the middle of the inner side of the bottom of the stress element. The insertion block 301 is of an L-shaped structure, the bottom of the insertion block is of an inclined structure, and the bottom of the insertion rod 302 is of an arc structure. The stress element 3 is arranged on the outer side of the main body 1 and is further connected with the stress groove 101 of the main body 1 through the insertion block 301, so that the stress element 3 can be stably connected and fixed with the main body 1, and the stress element 3 can be arranged before the main body 1 is arranged with the cross beam 2. Then, be connected with crossbeam 2 again, make the inside that connecting plate 303 can insert mounting groove 201 amount fixed by connecting piece 4, make this device can the firm installation, when meetting the earthquake, main part 1 removes, drives atress piece 3 simultaneously and removes together, makes atress piece 3 can remove to the inside of mounting groove 201, and then makes atress piece 3 can contact fixed, and then automatic reinforcing fixed effect. The insert 301 of the force-receiving member 3 is inserted into the force-receiving groove 101, and is further firmly connected with the main body 1, so that the main body 1 can drive the force-receiving member 3 to move together to buffer the impact force. The inserted rod 302 of the force-receiving member 3 is inserted into the slot 102, and the inserted rod 302 is inserted into the slot 102 to assist the fixing and installation, so that the force-receiving member 3 cannot move up and down.

The fixing plate 5 further includes a limiting groove 501 and a pressing plate 503. The fixing plate 5 is a rectangular plate-shaped structure, the bottoms of the two ends of the fixing plate are provided with I-shaped limiting grooves 501, and an inner groove 502 is arranged above the inside of the fixing plate 5. The inside of inner groove 502 is equipped with two rectangular plates, and inside still installs two springs, and the top outside of inner groove 502 is the slope column structure. The fixing plate 5 is installed at the front end of the cross beam 2, and the front end of the connecting member 4 and the T-shaped block are installed inside the limiting groove 501 of the fixing plate 5. The fixing plate 5 is configured such that the front end of the connector 4 can be inserted into the stopper groove 501 after the connector 4 is mounted. Meanwhile, the control plate 6 can be inserted into the inner groove 502, the spring can support the control plate 6 to move upwards, the top end of the spring can be inserted into the rectangular groove of the stress piece 3, and the device can be stably clamped and installed, so that the device cannot be loose. Meanwhile, the fixing device can be fixed and installed stably, the limiting groove 501 plays a role in installing the front end of the connecting piece 4 and the T-shaped block, the connecting piece 4 can be installed and used stably, the stressed piece 3 and the cross beam 2 are further fixed in an auxiliary mode and cannot be separated, the inner groove 502 is used for installing the pressing plate 503 through the spring, and the pressing plate 503 can receive the power of the spring to move.

The main body 1 includes two force-receiving grooves 101 and a slot 102. Two force receiving grooves 101 are provided on both sides of the main body 1. The force-bearing groove 101 is of an L-shaped structure, the bottom of the force-bearing groove is of an inclined structure, and a slot 102 is arranged in the middle of the bottom of the force-bearing groove 101. The two sides of the slot 102 are inclined structures, and the bottom of the slot 102 is an arc structure. The force-bearing groove 101 is used for embedding the insert block 301, so that the main body 1 and the force-bearing member 3 can bear force when being connected together. The slot 102 is used for inserting the installation inserted link 302, so that the stressed member 3 can move up and down along with the main body 1, and when the main body 1 is displaced, the stressed member 3 can be inserted into the installation slot 201 for auxiliary fixation.

Crossbeam 2 is L shape structure, and its inside front end is equipped with mounting groove 201, and the top both sides of mounting groove 201 are the slope column structure, and the inside both sides bottom of mounting groove 201 is equipped with fixed slot 202, and fixed slot 202 is the rectangle structure. Two rectangular channels are arranged at the bottoms of the two sides of the cross beam 2 and are positioned at the bottoms of the two sides of the mounting groove 201. The beam 2 is used for being spliced and fixed together with the main body 1, the mounting groove 201 is used for being inserted into the bottoms of the main body 1 and the stress piece 3, so that the stress piece 3 can be used for being mounted with the beam 2 in an auxiliary mode, and the fixing groove 202 is used for being inserted into the connecting piece 4, so that the connecting piece 4 can be used under stress together.

The connecting plate 303 is a U-shaped plate structure, and the connecting plate 303 is disposed at the bottoms of the two sides of the stressed member 3 and inserted into the two sides of the mounting groove 201. The connecting plate 303 is inserted into the mounting groove 201, so that the connecting member 4 can be inserted into the outer side of the connecting plate 303 when being mounted, and the force-receiving member 3 can be fixedly connected with the cross beam 2 together with the main body 1.

The connector 4 comprises a card slot 401. Connecting piece 4 is U-shaped plate column structure, and the both ends outside of connecting piece 4 is equipped with the T-shaped piece, and the inside both sides of connecting piece 4 are equipped with two draw-in grooves 401, and draw-in groove 401 is the rectangle structure. The connecting piece 4 plays a role in fixing the connecting plate 303, and further plays a role in auxiliary fixing. Meanwhile, the front end of the connecting piece 4 and the T-shaped block can be inserted into the limiting groove 501, so that the connecting piece 4 can be fixed, and the clamping groove 401 is used for being embedded into the middle position of the connecting plate 303, so that the connecting plate 303 can be fixed.

The pressing plate 503 is a rectangular plate-shaped structure, and two rectangular grooves are formed in the side edge of the pressing plate. A pressure plate 503 is installed inside the inner tank 502 with its bottom in contact with the top end of the spring. The clamp plate 503 is after the bottom end of the control panel 6 is inserted, and can be pushed upwards, so that the top end of the control panel 6 can be inserted into the groove of the stress member 3, and the control panel 6 can be assisted and limited by a user.

The control plate 6 is a rectangular plate-shaped structure, two control grooves 601 are arranged on the inner side of the bottom of the control plate, and the control grooves 601 are rectangular plate-shaped structures. The control panel 6 plays a role in auxiliary fixing of the fixing plate 5 and the stress element 3, so that the control panel 6 can be clamped and fixed. The control slot 601 is used for inserting a rectangular plate inside the inner installation slot 502, so that the control plate 6 can be limited and fixed.

The reinforcing member 7 is an L-shaped plate structure, two sides of the L-shaped plate structure are inclined structures, and a reinforcing groove 701 is formed in the reinforcing member 7. The reinforcing groove 701 is a T-shaped structure, and a rectangular groove is formed in the inner side of the top end of the reinforcing groove. Two clamping blocks 702 are arranged on two sides of the reinforcing member 7, and the clamping blocks 702 are rectangular structures. Reinforcing member 7 has played the effect of installing in the crossbeam 2 outside, and then has made crossbeam 2 install after, reinforcing member 7 can play reinforced crossbeam 2's effect, and when making this device meet the impact, crossbeam 2 can not be broken, and fixture block 702 has played the effect of inserting the rectangular channel inside of crossbeam 2 both sides, makes reinforcing member 7 can stabilize the installation.

When in use: when the device is needed, the main body 1 can be controlled to be connected with the cross beam 2. The stress piece 3 is firstly controlled to be connected with the main body 1, so that the insertion block 301 of the stress piece 3 can be inserted into the stress groove 101, the insertion rod 302 can be inserted into the insertion groove 102, and the stress piece 3 can be stably installed. Then, the control body 1 is coupled with the cross member 2 so that the force receiving member 3 can be positioned above the mounting groove 201. Meanwhile, the connection plate 303 is allowed to be inserted into the inside of the mounting groove 201. Next, the attachment of the connector 4 is controlled such that the card slot 401 of the connector 4 can be coupled with the middle position of the connection plate 303 so that the front end of the connector 4 can be inserted into the inside of the fixing groove 202. Then the fixing plate 5 is controlled to be installed, so that the front end of the installation connecting piece 4 and the T-shaped block can be embedded into the limiting groove 501 of the fixing plate 5, then the control plate 6 is installed, the bottom of the control plate 6 is inserted into the inner groove 502, and the pressing plate 503 is pressed, so that the spring can be compressed. The top end of the control plate 6 is aligned with the rectangular groove of the stress piece 3, the control plate 6 is loosened, the pressing plate 503 can receive the power of the spring to push the spring, and then the top end of the control plate 6 can be inserted into the rectangular groove of the stress piece 3. Then, control reinforcement 7 installation, make reinforcement 7 can install the front end at crossbeam 2, make fixture block 702 can insert the rectangular channel inside of crossbeam 2 both sides, and then make reinforcement 7 can assist fixed crossbeam 2, make this device when using, if when meetting earthquake or impact force, main part 1 drives atress piece 3 and removes, make atress piece 3 can insert the inside of mounting groove 201, and then carry out the automatic fixation, make main part 1 can not appear great displacement, and can be more firm.

It is to be noted that the foregoing is only illustrative of the preferred embodiments of the present invention and the technical principles employed. It will be understood by those skilled in the art that the present invention is not limited to the particular embodiments described herein, but is capable of various obvious changes, rearrangements and substitutions as will now become apparent to those skilled in the art without departing from the scope of the invention. Therefore, although the present invention has been described in greater detail by the above embodiments, the present invention is not limited to the above embodiments, and may include other equivalent embodiments without departing from the spirit of the present invention, and the scope of the present invention is determined by the scope of the appended claims.

Claims

1. The utility model provides a reinforced structure that is used for uneven node of concrete frame structure facade which characterized in that: the device comprises a main body (1), a cross beam (2), a stress piece (3), a connecting piece (4), a fixing plate (5), a control plate (6) and a reinforcing piece (7);

the main body (1) is of a rectangular long strip structure and is embedded in the mounting groove (201) of the cross beam (2); the stress piece (3) is arranged on the outer side of the main body (1); the connecting piece (4) is inserted into the fixing groove (202) of the cross beam (2) and is positioned in the middle position of the outer side of the connecting plate (303) of the stress piece (3); the fixed plate (5) is arranged at the front end of the cross beam (2); the top of the control plate (6) is inserted into the rectangular groove of the stress element (3), the bottom of the control plate is inserted into the inner groove (502) of the fixing plate (5), and the rectangular plate is inserted and installed in the control groove (601) of the control plate (6); the reinforcing member (7) is sleeved at the front end of the cross beam (2), the control plate (6) is embedded in a rectangular groove in the reinforcing groove (701) of the reinforcing member (7), and the clamping blocks (702) of the reinforcing member (7) are inserted into the rectangular grooves on the two sides of the cross beam (2);

the upper end and the lower end of the stress piece (3) are of wedge-shaped structures, two inserting blocks (301) are arranged on two sides inside the stress piece (3), an inserting rod (302) is arranged in the middle of the stress piece, a rectangular groove is formed in the middle of the inner side of the bottom of the stress piece, the inserting blocks (301) are inserted into the two stress grooves (101) of the main body (1), and the inserting rods (301) are inserted into the inserting grooves (102);

the fixing plate (5) is of a rectangular plate-shaped structure, the bottoms of the two ends of the fixing plate are provided with I-shaped limiting grooves, an inner groove is arranged above the inner part, two rectangular plates are arranged inside the inner groove and provided with two springs, the outer side of the top end of the inner groove is of an inclined structure, the front end of the connecting piece (4) is arranged in the limiting grooves, and T-shaped blocks are further arranged in the limiting grooves.

2. A reinforcing structure for a concrete frame structure facade unevenness joint according to claim 1, wherein: the main body (1) is made of concrete and comprises a slot (102) arranged in the middle of the bottom of the stress groove (101), the two sides of the slot (102) are of inclined structures, the bottom of the slot (102) is of an arc-shaped structure, the stress groove (101) is of an L-shaped structure, and the two stress grooves (101) are arranged on the two sides of the main body (1).

3. A reinforcing structure for a concrete frame structure facade unevenness node as claimed in claim 1, wherein: crossbeam (2) are L shape structure, and its inside front end is equipped with mounting groove (201), and the top both sides of mounting groove (201) are the slope column structure, and inside both sides bottom is equipped with fixed slot (202), and fixed slot (202) are the rectangle structure, and the both sides bottom of crossbeam (2) is equipped with two rectangular channels, and the rectangle trench is in the both sides bottom of mounting groove (201).

4. A reinforcing structure for a concrete frame structure facade unevenness joint according to claim 1, wherein: the plug block (301) is of an L-shaped structure, the bottom of the plug block is of an inclined structure, the bottom of the plug rod (302) is of an arc structure, the connecting plate (303) is of a U-shaped plate structure, and the connecting plate is arranged at the bottoms of two sides of the stress element (3) and is inserted into two sides of the mounting groove (201).

5. A reinforcing structure for a concrete frame structure facade unevenness joint according to claim 1, wherein: the connecting piece (4) comprises clamping grooves (401) which are of rectangular structures, the connecting piece (4) is of a U-shaped plate structure, T-shaped blocks are arranged on the outer sides of two ends of the connecting piece, and two clamping grooves (401) are arranged on two inner sides of the connecting piece.

6. A reinforcing structure for a concrete frame structure facade unevenness joint according to claim 1, wherein: the fixing plate (5) further comprises a pressing plate (503) arranged in the inner groove (502), the pressing plate is of a rectangular plate-shaped structure, two rectangular grooves are formed in the side edges of the pressing plate (503), and the bottom of the pressing plate (503) is in contact with the top end of the spring.

7. A reinforcing structure for a concrete frame structure facade unevenness joint according to claim 1, wherein: the control panel (6) is of a rectangular plate-shaped structure, two control grooves (601) are formed in the inner side of the bottom of the control panel, and the control grooves (601) are of rectangular plate-shaped structures.

8. A reinforcing structure for a concrete frame structure facade unevenness joint according to claim 1, wherein: the reinforcing member (7) is of an L-shaped plate structure, two sides of the L-shaped plate structure are of inclined structures, a reinforcing groove (701) is arranged inside the L-shaped plate structure, the reinforcing groove (701) is of a T-shaped structure, a rectangular groove is formed in the inner side of the top end of the reinforcing groove (701), two clamping blocks (702) are arranged on two sides of the reinforcing member (7), and the clamping blocks (702) are of rectangular structures.