JP2022122215A - Reinforcement device to cut connection beam destroyed by earthquake perfectly and method - Google Patents

Abstract

To provide a reinforcement device and a method that cut a connection beam destroyed by earthquake perfectly and attach an energy dissipation segment to non-energy dissipation segment.SOLUTION: The entire connection beam destroyed by earthquake is cut perfectly along a connection between a wall pillar and a connection beam and an attachment notch on an end face of the connection beam is polished to clean up. A beam out of I-shaped steel that is a non-energy dissipation segment according to the length of the connection beam destroyed by the earthquake is attached to an attachment notch at an attachment position of an energy dissipation segment.SELECTED DRAWING: Figure 1

Description

TECHNICAL FIELD The present invention relates to the technical field of repairing earthquake-damaged buildings, and more specifically to a reinforcing device and construction method for completely cutting earthquake-damaged connecting beams.

At present, most reinforced concrete buildings adopt the earthquake-resistant wall structure system, frame-shake-resistant wall. The resulting beam is called the connection beam.

In recent years, the rapid recovery of functions after an earthquake has become a research theme that attracts attention in the field of architecture. Most of the reinforced concrete buildings today still employ RC connecting walls, and under the reciprocating action of an earthquake, the RC connecting beams yield first to dissipate the load caused by the earthquake. In practical applications, both ends of the entire connecting beam of a high-rise building are embedded inside RC wall pillars, and due to their large mass, it is difficult to repair directly after an earthquake. In addition, replacement takes time and labor.

Due to the advanced economics and the demand for sustainable circles in modern society, a way to achieve rapid repair of building structural functions after an earthquake is imminent to ensure safety. Therefore, there is an urgent need for a repair method for connecting beams in reinforced concrete buildings after an earthquake.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a reinforcing device and method for completely cutting connecting beams destroyed by an earthquake.

As a technical solution of the present invention, a reinforcing device for completely cutting an earthquake-broken connecting beam includes a non-energy-dissipating segment whose ends are respectively attached to the two cut ends of the earthquake-broken connecting beam, said non-energy The energy dissipating segment on the dissipating segment can be embedded.

In one aspect of the invention, said non-energy dissipative segment is a beam of I-beam,
the energy-dissipating segment includes an energy-dissipating block and a first connecting piece attached to both ends of the energy-dissipating block for connecting beams of I-beam;
The energy-dissipating block comprises: an energy-dissipating block body; two energy-dissipating components mounted inside the energy-dissipating block body; an energy-dissipating ball mounted inside the energy-dissipating block body and located between the two energy-dissipating components; an energy-dissipating pad mounted inside the block body and located at the lower end of the two energy-dissipating components, and an energy-transmitting block movably mounted on the upper end of the energy-dissipating block body;
said energy dissipating component comprises a mounting block, an upper slider, a lower slider, a left slider and a right slider movably mounted on the mounting block upper end surface, lower end surface, left end surface and right end surface, respectively, between said upper slider and lower slider; is further provided with a spring, the left slider and the right slider have the same structure, and the left slider,
The contact end surfaces of the left slider, the right slider, the upper slider, and the lower slider are arranged to face each other with the right slider mounting block as the center, and
The left and right ends of the energy-dissipating ball are respectively connected to one end of the left slider of one energy-dissipating component and one end of the right-hand slider of the other energy-dissipating component, and the first connecting part is the left slider of one energy-dissipating component. the other end, connected to the other end of the right slider of the other energy dissipation component,
The energy-dissipating pad-to-lower slider connection, the energy-transmitting block-to-upper slider connection, and the use of this reinforcing device The energy-dissipating segment has a certain self-recovery ability, and has a seismic effect due to its own repair ability when responding to small seismic energy. can be realized.

In one aspect of the present invention, the energy-dissipating block further comprises an energy-dissipating component, wherein there are two of the energy-dissipating components, two energy-dissipating components mounted inside the energy-dissipating block body, respectively, the top end of the energy-dissipating ball and the energy-dissipating ball located at the bottom of
The energy dissipating component includes a contact energy transfer block with one end in contact with the energy dissipating ball, a damper connected to the other end of the contact energy transfer block, the damper adopting a prior art damper, and the energy dissipating component The dissipative segment can be made more seismic and more self-healing.

As one aspect of the present invention, the first connection component includes a connection block having an I-shaped structure, an I-shaped slot opened in the connection block, and an I-shaped slot provided in a longitudinal end face of the connection block and passing through the I-shaped slot. a first locking notch and a second locking notch located in a lateral end face of the connecting block and extending through the I-shaped slot;
The connecting end of the non-energy-dissipating segment with the first connecting piece can be inserted into the I-shaped slot, and the connecting end of the non-energy-dissipating segment with the first connecting piece corresponds to the first fixing notch. The first connecting groove, the second connecting groove corresponding to the second fixed notch are provided, and the non-energy-dissipating segment and the energy-dissipating segment are connected by high-strength bolts using the fixed notch and the connecting groove. and convenient for late replacement.

Preferably, the non-energy dissipating segment is connected to the cut end via a second connecting piece, the second connecting piece being an embedded block placed embedded inside the wall pillar and the embedded block side includes a connection sheet for connecting non-energy dissipating segments provided in the wall pillar interior through the embedded block to clean up the connection area of the connection beam and the wall pillar when cutting the earthquake-damaged connecting beam After embedding the embedded block inside the wall pillar by soldering rebar, it is reinforced with reinforcing bolts to connect the non-energy dissipating segment and connecting sheet.

In one aspect of the invention, the reinforcement device is used to replace an earthquake-damaged connecting beam, wherein the earthquake-damaged connecting beam is specifically the fractured part of an earthquake-damaged reinforced concrete connecting beam, the reinforced concrete connection The aspect ratio of the beam is L/H≦5.
The present invention provides a construction method for cutting and reinforcing all earthquake-damaged connecting beams, which includes the following steps:
Step 1: Cut the earthquake-damaged connecting beams 1) cut all the earthquake-damaged connecting beams along the joints of the wall pillars and the connecting beams;
2) Cut a mounting notch in the end face of the pilaster from which the seismically destroyed connecting beam was cut;
3) Grind the mounting notch and clean up the cut until the wall post rebar is exposed;
Step 2: Attachment of the reinforcement device 1) Cut the attachment location of the energy-dissipating segment on the non-energy-dissipating segment;
Select the same length of I-beam according to the length of the seismic failure connection beam, cut the installation position of the energy-dissipating segment in the selected I-beam, and cut two non-energy-dissipating segments , and in the meantime, when cutting the mounting position of the energy dissipating segment, it is necessary to ensure a distance equal to the depth of the mounting notch on both ends of the I-beam,
2) Install one of the cut non-energy dissipative segments into one mounting notch, install the energy dissipative segment, and then install the other cut non energy dissipative segment between the energy dissipative segment and the other mounting notch.

Compared with the prior art, the beneficial effects of the present invention are as follows.
1. The method of the present invention is rational in design, effectively replaceably repairs earthquake-damaged connection beams, and the repaired connection beams have high energy dissipation capacity;
2. The whole reinforcement device proposed by the present invention has reasonable structural design, has suitable self-recovery ability when responding to certain earthquakes, and can withstand the late earthquake failure when responding to large seismic energy failures. convenient to replace the energy dissipating segment,
3. Since the present invention can handle a large plastic rotation angle as a whole, it has high earthquake resistance performance and is suitable for a wide range of promotions.

2 is a flow chart of the method of the invention; FIG. 4 is an exploded view of a reinforcement device according to Embodiment 2 of the present invention; FIG. 4 is a schematic diagram of the external structure of the energy-dissipating segment of Example 2 of the present invention; FIG. 4 is a schematic diagram of the internal structure of the energy-dissipating segment of Example 2 of the present invention; FIG. 4 is a schematic diagram of the external structure of the energy-dissipating segment of Example 3 of the present invention; FIG. 4 is an exploded view of a reinforcement device according to Embodiment 4 of the present invention; 1 is a schematic diagram of the internal structure of the energy-dissipating segment of Example 1 of the present invention; FIG.

[Description of symbols]
1 energy dissipative block 11 energy dissipative block body 12 energy dissipative component 120 mounting block 121 upper slider 122 lower slider 123 left slider 124 right slider 125 spring 13 energy dissipative ball 14 energy dissipative pad 15 energy transfer block 16 energy dissipative component 161 contact energy transfer block 162 damper 2 first connecting piece 21 connecting block 22 I-shaped slot 23 first locking notch 24 second locking notch 3 second connecting piece 31 embedded block 32 connecting sheet

Example 1: A reinforcement device for completely severing an earthquake-failed connecting beam includes a non-energy-dissipating segment whose ends are each attached to two severed ends of an earthquake-failed connecting beam, wherein the energy on said non-energy-dissipating segment is It is possible to place the dissipative segments embedded,
Said non-energy-dissipating segment is a beam of I-beam, as shown in FIGS. comprising first connecting pieces 2 provided at both ends for connecting I-beam beams,
As shown in FIG. 7, the energy-dissipating block 1 comprises an energy-dissipating block body 11, two energy-dissipating components 12 mounted inside the energy-dissipating block body 11, and two energy-dissipating components 12 mounted inside the energy-dissipating block body 11. Energy-dissipating ball 13 located between, energy-dissipating block body 11
comprising an energy dissipating pad 14 mounted inside and located at the lower end of the two energy dissipating components 12, and an energy transmission block 15 movably mounted at the upper end of the energy dissipating block body 11;
The energy dissipative components 12 are mounted on mounting blocks 120, respectively mounting blocks 12
An upper slider 121, a lower slider 122, a left slider 123, and a right slider 124 are movably attached to the upper, lower, left, and right end surfaces of 0, and a spring 125 is further provided between the upper slider 121 and the lower slider 122. provided, left slider 1
23. The right slider 124 has the same structure. The left slider 123 and the right slider 124 are arranged facing each other with the mounting block 120 as the center. are the slopes, respectively, and
The left and right ends of the energy-dissipating ball 13 are respectively connected to one end of the left slider 123 of one energy-dissipating component 12 and one end of the right-hand slider 124 of the other energy-dissipating component 12, and the first connecting part 2 is connected to one energy-dissipating component The other end of the left slider 123 of the component 12, the other energy dissipation component 12
is connected to the other end of the right slider 124 of the
Energy dissipating pad 14 is connected to lower slider 122 and energy transfer block 15 is connected to upper slider 121 .

The construction method of the reinforcing device includes the following steps.
Step 1: Cutting of earthquake-damaged connecting beams 1) Cut all the earthquake-damaged connecting beams along the joints of wall pillars and connecting beams. is a fractured part, the aspect ratio of the reinforced concrete connecting beam is L/H = 2.5,
2) Cut a mounting notch in the end face of the pilaster from which the seismically destroyed connecting beam was cut;
3) Grind the mounting notch and clean up the cut until the wall post rebar is exposed;
Step 2: Installation of the reinforcement device 1) Cut the installation position of the energy-dissipating segment into the non-energy-dissipating segment, select the same length of I-beam according to the length of the seismically fractured connection beam, and select I
Cut the installation position of the energy-dissipating segment in the beam of the section steel, obtain two cut non-energy-dissipating segments, meanwhile, when cutting the installation position of the energy-dissipating segment, the depth of the installation notch at both ends of the I-shaped steel beam should ensure a distance equal to
2) Mount either one of the cut non-energy-dissipating segments in one mounting notch, solder the energy-dissipating segment to the non-energy-dissipating segment mounted in the mounting notch by means of the first connecting piece 2, then cut the other; non-dissipative segment between the energy-dissipative segment and the other mounting notch.

Example 2: Different from Example 1, the aspect ratio of the reinforced concrete connecting beam is L/H=1.5.

Example 3: Different from Example 1 in the following points, as shown in FIGS.
is an I-shaped structure connection block 21, an I-shaped slot 2 opened in the connection block 21
2, a second fixing notch 23 provided on the longitudinal end face of the connecting block 21 and passing through the I-shaped slot 22, and a second fixing notch 23 provided on the lateral end face of the connecting block 21 and passing through the I-shaped slot 22; including a notch 24;
The connecting end of the non-energy-dissipating segment and the first connecting piece 2 can be inserted into the I-shaped slot 22 , and the connecting end of the non-energy-dissipating segment and the first connecting piece 2 corresponds to the second fixing notch 23 . A first connecting groove corresponding to the second fixing notch 24 and a second connecting groove corresponding to the second fixing notch 24 are provided.
The construction method of the reinforcing device includes the following steps:
Step 1: Cutting of earthquake-damaged connecting beams 1) Cut all the earthquake-damaged connecting beams along the joints of wall pillars and connecting beams. is a fractured part, the aspect ratio of the reinforced concrete connecting beam is L/H = 4.5,
2) Cut a mounting notch in the end face of the pilaster from which the seismically destroyed connecting beam was cut;
3) Grind the mounting notch and clean up the cut until the wall post rebar is exposed;
Step 2: Installation of the reinforcement device 1) Cut the installation position of the energy-dissipating segment into the non-energy-dissipating segment, select the same length of I-beam according to the length of the seismically fractured connection beam, and select I
Cut the mounting position of the energy-dissipating segment in the beam of the section steel, obtain the cut two non-energy-dissipating segments, in the meantime, when cutting the mounting position of the energy-dissipating segment, cut the mounting notches on both ends of the beam of I-beam It is necessary to ensure a distance equal to the depth of the
1) Install one of the cut non-energy-dissipating segments in one mounting notch, aligning the I-shaped slot 22 on the first connecting piece 2 at one end of the energy-dissipating segment with the I-beam beam on the mounting notch; Mounting, using reinforcing bolts, sequentially fixed with the first connecting groove by the first fixing notch 23, fixed with the second connecting groove by the second fixing notch 24, then cut the other non-energy-dissipating segment between the energy dissipating segment and the other mounting notch.

Example 4: Different from Example 3, the construction method of the reinforcing device includes the following steps:
Step 1: Cutting of earthquake-damaged connecting beams 1) Cut all the earthquake-damaged connecting beams along the joints of wall pillars and connecting beams. is a fractured part and the aspect ratio of the reinforced concrete connecting beam is L/H=3;
2) Cut a mounting notch in the end face of the pilaster from which the seismically destroyed connecting beam was cut;
3) Grind the mounting notch and clean up the cut until the wall post rebar is exposed;
Step 2: Installation of the reinforcement device 1) Cut the installation position of the energy-dissipating segment into the non-energy-dissipating segment, select the same length of I-beam according to the length of the seismically fractured connection beam, and select I
Cut the mounting positions of the energy-dissipating segments in the beam of the section steel, obtain two cut non-energy-dissipating segments, in the meantime, cut the mounting notches on both ends of the beam of I-beam when cutting the mounting positions of the energy-dissipating segments. It is necessary to ensure a distance equal to the depth,
2) Attaching the energy-dissipating segment between the two cut non-energy-dissipating segments to form the entire repaired connecting beam, the two non-energy-dissipating cut segments being sequentially attached to the first connecting pieces 2 at both ends of the energy-dissipating segment; upper I-shaped slot 22
and then fixed with a first connecting groove by means of a first fixing notch 23 and a second connecting groove by means of a second fixing notch 24 in sequence using a reinforcing bolt, after which the repaired connection Install the entire beam between the two mounting notches.

Example 5: Different from Example 3, the energy-dissipating block 1 further comprises an energy-dissipating component 16, as shown in FIG. 11 and located at the upper and lower ends of the energy dissipating ball 13, respectively;
The energy dissipating component 16 includes a contact energy transfer block 161 with one end contacting the energy dissipating ball 13, a damper 162 connected to the other end of the contact energy transfer block 161, wherein the damper 162 is a commercially available damper. be.
The construction method of the reinforcing device includes the following steps:
Step 1: Cutting of earthquake-damaged connecting beams 1) Cut all the earthquake-damaged connecting beams along the joints of wall pillars and connecting beams. is a fractured part, the aspect ratio of the reinforced concrete connecting beam is L/H = 3.5,
2) Cut a mounting notch in the end face of the pilaster from which the seismically destroyed connecting beam was cut;
3) Grind the mounting notch and clean up the cut until the wall post rebar is exposed;
Step 2: Installation of the reinforcement device 1) Cut the installation position of the energy-dissipating segment into the non-energy-dissipating segment, select the same length of I-beam according to the length of the seismically fractured connection beam, and select I
Cut the mounting positions of the energy-dissipating segments in the beam of the section steel, obtain two cut non-energy-dissipating segments, in the meantime, cut the mounting notches on both ends of the beam of I-beam when cutting the mounting positions of the energy-dissipating segments. It is necessary to ensure a distance equal to the depth,
3) Install one of the cut non-energy-dissipating segments into one mounting notch and position the I-shaped slot 22 on the first connecting piece 2 at one end of the energy-dissipating segment into the I-beam beam above the mounting notch. Installed together, fixed with the first connecting groove by the first fixing notch 23 using the reinforcing bolt, and fixed with the second connecting groove by the second fixing notch 24, then cut the other non-energized Install the dissipative segment between the energy dissipative segment and the mounting notch on the other side.

Example 6: Different from Example 5, the construction method of the reinforcing device includes the following steps:
Step 1: Cutting of earthquake-damaged connecting beams 1) Cut all the earthquake-damaged connecting beams along the joints of wall pillars and connecting beams. is a fractured part, the aspect ratio of the reinforced concrete connecting beam is L/H = 2.6,
2) Cut a mounting notch in the end face of the pilaster from which the seismically destroyed connecting beam was cut;
3) Grind the mounting notch and clean up the cut until the wall post rebar is exposed;
Step 2: Installation of the reinforcement device 1) Cut the installation position of the energy-dissipating segment into the non-energy-dissipating segment, select the same length of I-beam according to the length of the seismically fractured connection beam, and select I
Cut the mounting positions of the energy-dissipating segments in the beam of the section steel, obtain two cut non-energy-dissipating segments, in the meantime, cut the mounting notches on both ends of the beam of I-beam when cutting the mounting positions of the energy-dissipating segments. It is necessary to ensure a distance equal to the depth,
4) Attaching the energy-dissipating segment between the two cut non-energy-dissipating segments to form the entire repaired connection beam, the two non-energy-dissipating cut segments being sequentially attached to the first connecting pieces 2 at both ends of the energy-dissipating segment. upper I-shaped slot 22
and then fixed with a first connecting groove by means of a first fixing notch 23 and a second connecting groove by means of a second fixing notch 24 in sequence using a reinforcing bolt, after which the repaired connection Install the entire beam between the two mounting notches.

Example 7: Different from Example 5, as shown in FIG. 6, the non-energy dissipating segment is connected with the cut end via a second connecting part 3, the second connecting part 3 being inside the pilaster It includes an embedded block 31 provided embedded and a connection sheet 32 provided on the side of the embedded block 31 to connect the non-energy dissipating segments.
The construction method of the reinforcing device includes the following steps:
Step 1: Cutting of earthquake-damaged connecting beams 1) Cut all the earthquake-damaged connecting beams along the joints of wall pillars and connecting beams. is a broken part, the aspect ratio of the reinforced concrete connection beam is L / H = 2.5,
2) Cut a mounting notch in the end face of the pilaster from which the seismically destroyed connecting beam was cut;
3) Grind the mounting notch and clean up the cut until the wall post rebar is exposed;
Step 2: Installation of the reinforcement device 1) Cut the installation position of the energy-dissipating segment into the non-energy-dissipating segment, select the same length of I-beam according to the length of the seismically fractured connection beam, and select I
Cut the mounting positions of the energy-dissipating segments in the beam of the section steel, obtain two cut non-energy-dissipating segments, in the meantime, cut the mounting notches on both ends of the beam of I-beam when cutting the mounting positions of the energy-dissipating segments. It is necessary to ensure a distance equal to the depth,
5) mounting the second connecting part 3 between the two mounting notches by means of the embedding block 31 and mounting one of the cut non-energy dissipating segments to one connecting sheet 32;
Install the I-shaped slot 22 on the first connecting piece 2 at one end of the energy dissipating segment in alignment with the I-beam beam on the mounting notch, using a reinforcing bolt to sequentially lock the first through the first fixing notch 23 . It is fixed with the connecting groove and fixed with the second connecting groove by the second fixing notch 24 , and then the other cut non-energy-dissipating segment is attached between the energy-dissipating segment and the other connecting sheet 32 .

Example 8: Different from Example 6, the construction method of the reinforcing device includes the following steps:
Step 1: Cutting of earthquake-damaged connecting beams 1) Cut all the earthquake-damaged connecting beams along the joints of wall pillars and connecting beams. is a broken part, the aspect ratio of the reinforced concrete connection beam is L / H = 3.2,
2) Cut a mounting notch in the end face of the pilaster from which the seismically destroyed connecting beam was cut;
3) Grind the mounting notch and clean up the cut until the wall post rebar is exposed;
Step 2: Installation of the reinforcement device 1) Cut the installation position of the energy-dissipating segment into the non-energy-dissipating segment, select the same length of I-beam according to the length of the seismically fractured connection beam, and select I
Cut the mounting positions of the energy-dissipating segments in the beam of the section steel, obtain two cut non-energy-dissipating segments, in the meantime, cut the mounting notches on both ends of the beam of I-beam when cutting the mounting positions of the energy-dissipating segments. It is necessary to ensure a distance equal to the depth,
6) Attaching the energy-dissipating segment between the two cut non-energy-dissipating segments to form the entire repaired connecting beam, and placing the two cut non-energy-dissipating segments sequentially on the first connecting piece 2 at each end of the energy-dissipating segment. and then fixed with the first connecting groove by the first fixing notch 23 and with the second connecting groove by the second fixing notch 24 in sequence using the reinforcing bolt. , and then attach the second connecting piece 3 to the cut two non-energy dissipating segment outer ends, and the embedding block 31 attaches the second connecting piece 3 between the two mounting notches.

Experimental example: The performance of the reinforcement devices presented in Examples 1, 3, 5, and 7 was experimentally measured in comparison with a comparative set, wherein the non-energy-dissipating segment and the energy-dissipating segment of the comparative set were Q345 steel, the energy dissipating segment is provided with a flange and a web, in which the flange adopts Q345 steel, the web adopts LY225 low yield point steel, the non-energy dissipating segment, the end plate between the energy dissipating segment
- Connected by shear key.
The specific steps are as follows: for each of the reinforcement devices presented in Examples 1, 3, 5 and 7, the connecting beam is bent by applying a load to the connecting beam until the first failure occurs; The energy dissipating segment is then removed and replaced while the connecting beam still has radiance, the replaced connecting beam is reloaded and stopped to 0.020 rad of radiance, after which the connecting beam has radiance of 0. Further loads were applied to the connecting beams until the second breaking phenomenon occurred, with increasing velocities of 0.002 rad/min, and specific experimental data are shown in Table 1:
Table 1: Data table obtained by experiments for Examples 1, 3, 5, 7 and the comparative set

Conclusion: The connecting beam structure constructed by the reinforcement device of the present invention has a significantly increased critical radian and reduces the time required to replace the energy dissipating segment after an earthquake failure.

Claims (6)

comprising a non-energy-dissipating segment attached to two severed ends of a connecting beam, each of which has seismic failure at each end, wherein the energy-dissipating segment may be positioned embedded on said non-energy-dissipating segment;
said non-energy dissipative segment is a beam of I-beam;
said energy dissipating segment comprises an energy dissipating block (1) and first connecting pieces (2) attached to both ends of said energy dissipating block (1) for connecting beams of I-beam,
Said energy dissipating block (1) comprises: an energy dissipating block body (11), two energy dissipating components (12) mounted inside the energy dissipating block body (11), 2 mounted inside the energy dissipating block body (11) an energy-dissipating ball (13) positioned between two said energy-dissipating components (12), an energy-dissipating pad (14) mounted inside an energy-dissipating block body (11) and positioned at the lower end of two said energy-dissipating components (12), and an energy transfer block (15) attached to the upper end of the energy dissipating block body (11),
Said energy dissipating component (12) comprises a mounting block (120), an upper slider (121) and a lower slider (122) movably mounted on the top, bottom, left and right end surfaces of the mounting block (120) respectively. , a left slider (123) and a right slider (124), a spring (125) is provided between the upper slider (121) and the lower slider (122), and the left slider (123) and the right slider (12
4), the left slider (123) and the right slider (124) are arranged facing each other around the mounting block (120), and the left slider (123), the right slider (124) and the upper part The contact end surfaces of the slider (121) and the lower slider (122) are inclined surfaces,
the left and right ends of the energy dissipating ball (13) are respectively connected to one end of the left slider (123) of one energy dissipating component (12) and one end of the right slider (124) of the other energy dissipating component (12); first connecting piece (2)
is connected to the other end of the left slider (123) of one energy dissipative component (12) and the other end of the right slider (124) of the other energy dissipative component (12),
Completely cutting a seismically ruptured connecting beam, characterized in that said energy dissipating pad (14) is connected to a lower slider (122) and said energy transmission block (15) is connected to an upper slider (121). reinforcement device. Said energy-dissipating block (1) further comprises an energy-dissipating component (16), said energy-dissipating component (16) being two, two energy-dissipating components (16) being mounted inside the energy-dissipating block body (11) located respectively at the upper and lower ends of the energy-dissipating ball (13),
Said energy dissipating component (16) comprises a contact energy transfer block (161), one end of which contacts the energy dissipating ball (13), said contact energy transfer block (1
61), comprising a damper (162) connected to the other end of 61). Said first connection part (2) comprises an I-shaped structure connection block (21), said connection block (
21), a first fixing notch (23) provided in the longitudinal end face of the connecting block (21) and passing through the I-shaped slot (22), and the connecting block (21) ) through the I-shaped slot (22) in the lateral end face of the I-shaped slot (22);
said non-energy-dissipating segment connecting end with the first connecting piece (2) is insertable into the I-shaped slot (22), said non-energy-dissipating segment connecting end with the first connecting piece (2) , the first connecting groove corresponding to the first fixing notch (23) and the second fixing notch (2
2. Reinforcement device according to claim 1, characterized in that a second connection groove corresponding to 4) is provided. said non-energy dissipative segment is connected to the cut end via a second connecting piece (3);
The second connecting part (3) is an embedded block (31) embedded in the interior of the wall pillar,
and connecting sheets (32) provided on the sides of the embedded blocks (31) for connecting the non-energy dissipating segments. Said reinforcement device is used to replace an earthquake-damaged connection beam, said earthquake-damaged connection beam is specifically a broken part of a reinforced concrete connection beam after an earthquake, and the aspect ratio of the reinforced concrete connection beam is L/H 2. The reinforcement device of claim 1, wherein ≤5. A construction method for cutting and reinforcing all earthquake-damaged connection beams using the reinforcement device according to any one of claims 1 to 5,
Step 1: Cut the earthquake-damaged connecting beams 1) cut all the earthquake-damaged connecting beams along the joints of the wall pillars and the connecting beams;
2) Cut a mounting notch in the end face of the pilaster from which the seismically destroyed connecting beam was cut;
3) Grinding the mounting notch and cleaning up the cut until the rebar portion of the pilaster is exposed;
Step 2: Attachment of the reinforcement device 1) Cut the attachment location of the energy-dissipating segment on the non-energy-dissipating segment;
Select the same length of I-beam according to the length of the seismic failure connection beam, cut the installation position of the energy-dissipating segment in the selected I-beam, and cut two non-energy-dissipating segments , and in the meantime, when cutting the mounting position of the energy dissipating segment, it is necessary to ensure a distance equal to the depth of the mounting notch on both ends of the I-beam,
7) attaching one of the cut non-energy dissipative segments to one mounting notch, attaching the energy dissipating segment, and then mounting the other cut non energy dissipating segment between the energy dissipative segment and the other mounting notch;
A construction method characterized by comprising

Images