CN216476504U - Integral reinforcing structure of ancient building - Google Patents

Abstract

The application relates to an integral reinforcing structure of an ancient building, which relates to the field of building reinforcing technology and comprises a reinforcing cylinder for supporting and jacking eave of the ancient building, wherein the reinforcing cylinder is vertically placed on the ground, the top of the reinforcing cylinder is connected with an adjustable cushion block, the adjustable cushion block comprises an upper block body and a lower block body, one side of the upper block body is rotatably connected to the lower block body, and an adjustable included angle is formed between the upper block body and the lower block body; an adjusting piece is arranged between the upper block body and the lower block body and used for controlling the upper block body to be close to or far away from the lower block body; reinforced structure in this application supports ancient building eaves through consolidating the cylinder and adjustable cushion cooperation, can the adaptability, goes up the clearance between block and the ancient building eaves less, consolidates the cylinder and can adjust the cushion and consolidate the effect better to the support of ancient building.

Description

Integral reinforcing structure of ancient building

Technical Field

The application relates to the field of building reinforcement technology, in particular to an integral reinforcing structure of an ancient building.

Background

Ancient buildings generally refer to civil buildings and public buildings before the country construction with historical significance, and the main structural form of the ancient buildings is a wood structure. Due to the fact that the construction years are long and the influence of natural disasters is added, most of ancient building structures are damaged in different degrees, mainly in the forms of wood cracking, decay, component deformation and node tenon pulling, so that the performances of the ancient building structures with wood structures are seriously degraded, great potential safety hazards exist, and repairing and reinforcing are needed.

At present, the repairing and reinforcing of ancient buildings are generally to directly reinforce the whole wooden frame on the basis of not contacting with a tile roof and not detaching a framework, the whole reinforcing method mainly comprises three methods of frame falling overhaul, displaced member correction, whole lifting and the like, and in the three whole reinforcing methods, structures such as a hydraulic jack system or a reinforcing column body and the like are required to be installed at proper positions beside a column-beam structure of the ancient building, and a house beam and other structures such as eave and the like are upwards jacked by means of a node underpinning method to perform high-quality connection repairing on the house; when the eave of the historic building is jacked upwards, the cushion block is adopted to perform adaptive cushion lifting between the top of the reinforcing structures such as the hydraulic jack or the reinforcing column body and the eave, so that the gap between the reinforcing member and the house is reduced, and the eave of the historic building is supported and reinforced well.

To the correlation technique among the above-mentioned, the inventor discovers at present repair reinforcement in-process, to the eaves that inclination is different, need adopt the different cushion or polylith cushion of inclination to fill up the clearance between reinforced structure tops such as hydraulic jack or reinforcement cylinder and the eaves and rise, and the actual construction is comparatively inconvenient, and easily breaks away from relatively between reinforced structure such as cushion and hydraulic jack or reinforcement cylinder, influences the reinforcing effect to ancient building.

SUMMERY OF THE UTILITY MODEL

In order to reduce the clearance between reinforcing member and the ancient building eaves when reinforcing member jacking ancient building eaves more convenient, comparatively stable repairs the ancient building and consolidates, this application provides an ancient building's whole reinforced structure.

The application provides a pair of ancient building's whole reinforced structure adopts following technical scheme:

the integral reinforcing structure of the historic building comprises a reinforcing column body for supporting and jacking eave of the historic building, wherein the reinforcing column body is vertically placed on the ground, the top of the reinforcing column body is connected with an adjustable cushion block, the adjustable cushion block comprises an upper block body and a lower block body, one side of the upper block body is rotatably connected onto the lower block body, and an adjustable included angle is formed between the upper block body and the lower block body; and an adjusting piece is arranged between the upper block body and the lower block body and is used for controlling the upper block body to be close to or far away from the lower block body.

By adopting the technical scheme, the reinforcing column body and the adjustable cushion block can jointly support the ancient building eave on the ground, the distance between the upper block body and the lower block body is controlled by the adjusting piece, the included angle between the upper block body and the lower block body can be adjusted, and the adjustable cushion block can adaptively lift the eave with different inclination angles, support and reinforce the ancient building eave, a plurality of cushion blocks or grinding cushion blocks are not required to lift the gap between the ancient building eave and the reinforcing column body, and the operation is convenient in actual construction; and adjustable cushion connects in consolidating the cylinder top, and the skew takes place for the difficult relative reinforcement cylinder of adjustable cushion, consolidates the cylinder and more stable to the support of ancient building eaves with adjustable cushion, and it is better to consolidate the effect.

Optionally, the adjusting element includes a screw rod and a sliding block, a linear mounting groove is formed in the upper surface of the lower block, the length direction of the mounting groove is perpendicular to the connecting line between the upper block and the lower block, the axial direction of the screw rod is parallel to the length direction of the mounting groove, and the screw rod penetrates through two side walls of the mounting groove in the linear direction and is mounted in the mounting groove; the sliding block is located between the upper block body and the lower block body, the lower portion of the sliding block is sleeved with the lower portion of the sliding block and is connected to the screw rod in a threaded mode, the lower portion of the sliding block is in butt joint with the mounting groove of the lower block body along two side walls in the width direction, and the lower surface of the upper block body is suitable for being in butt joint with the upper portion of the sliding block.

Through adopting the above technical scheme, when the lead screw rotates, the driving force of wire winding rod pivoted is provided for the sliding block, block and mounting groove cooperation down, the restriction has been carried out to the rotation of sliding block, the rotation of change sliding block wire winding rod is for the rectilinear slide along the lead screw, make the sliding block can be close to or keep away from last block and block down and be connected the position along with the rotation straight line of lead screw, and then make the last block of keeping away from on the block and block down one side that is connected the position keep away from or be close to down the block, comparatively convenient realization to last block and the regulation of contained angle down between the block.

Optionally, a rotating shaft is further arranged at a joint of the upper block and the lower block, the upper block and the lower block are rotatably connected through the rotating shaft, the screw rod is perpendicular to the rotating shaft, and the rotating shaft is located above the screw rod; the worm is sleeved and fixedly connected with the rotating shaft at the position, perpendicular to the screw rod, of the rotating shaft, a worm is connected to one end, close to the rotating shaft, of the screw rod, the worm is coaxially arranged with the screw rod, the worm is meshed and connected with the worm, and the worm is fixedly connected to the lower portion of the upper block.

By adopting the technical scheme, when the screw rod is rotated, the turbine can coaxially rotate along with the screw rod so as to drive the turbine to rotate, the turbine drives one side, far away from the rotating shaft, of the upper block body to approach or be far away from the lower block body around the rotating shaft, and the included angle between the upper block body and the lower block body is adjusted; in this in-process, when turbine and vortex pole played further regulation to last block and the contained angle between the block down, can cooperate lead screw and sliding block, further spacing to the rotation of lead screw for the sliding block is difficult for taking place to remove in the mounting groove because of the pressure of the ancient building eaves that last block and last block born when the lead screw no longer rotates, makes adjustable cushion and the reinforcement cylinder can be more stable support the ancient building eaves.

Optionally, a dial is installed on the outer wall of one side of the block body far away from the rotating shaft, one end of the screw rod far away from the rotating shaft is located in the dial, the middle point of the dial is located on the axis of the screw rod, a scroll rod is combined with the screw rod, the scroll rod rotates for one circle, and the turbine rotates for half a circle around the rotating shaft.

Through adopting above-mentioned technical scheme, observe the calibrated scale, the staff can be comparatively convenient control the turned angle of lead screw, control the block and the contained angle between the block down promptly for the inclination of adaptation ancient building eaves that adjustable cushion can be better.

Optionally, a wedge-shaped groove is further formed in one side, close to the lower block, of the upper block, the upper portion of the sliding block is suitable for being connected in the wedge-shaped groove in a sliding mode, and the groove depth of the wedge-shaped groove is gradually reduced from one side, far away from the rotating shaft, to one side, close to the rotating shaft; when the sliding block slides to the mounting groove and is far away from the end part of one end of the rotating shaft, the lower surface of the upper block body is suitable for abutting against the lower block body, and the upper surface and the lower surface of the upper block body and the upper surface and the lower surface of the lower block body are horizontal planes.

Through adopting above-mentioned technical scheme, the wedge groove can hold the sliding block for the surface of last block and lower block can be in the horizontality, adapts to the support to the ancient building eaves that the inclination is 0, enlarges the support range of adjustable cushion and reinforcement cylinder to the ancient building eaves.

Optionally, the upper portion of the sliding block is connected with a flexible pad, and the lower surface of the upper block body is suitable for abutting against the flexible pad.

Through adopting above-mentioned technical scheme, the flexible pad can enlarge the sliding block and to the holding area of last block between last block and sliding block, and more stable supports last block for the bearing gravity and the pressure of ancient building eaves that reinforced structure can be better.

Optionally, the upper portion of the lower block body is located on two sides of the mounting groove, and a limiting groove is further formed in the two sides of the mounting groove, a limiting block is convexly arranged on the lower portion of the sliding block and is connected in the limiting groove in a sliding mode.

Through adopting above-mentioned technical scheme, spacing groove and stopper cooperation can further carry on spacingly to the motion of sliding block for the sliding block can be more smooth and easy and steady carry out linear motion along the lead screw.

Optionally, the limiting block is a T-shaped block, a cross-sectional area of one side of the limiting block, which is far away from the sliding block, is larger than a cross-sectional area of one side of the limiting block, which is close to the sliding block, and the limiting groove is a T-shaped groove corresponding to the T-shaped block.

Through adopting above-mentioned technical scheme, T-shaped piece and T-shaped groove cooperate, are better to the spacing effect of sliding block, and the sliding of sliding block on the lead screw is more steady.

In summary, the present application includes at least one of the following beneficial technical effects:

by arranging the reinforcing cylinder, the adjustable cushion block and the adjusting piece, the sliding block can be driven to linearly approach or depart from the connecting part of the upper block body and the lower block body by rotating the screw rod, so that the eave with different inclination angles can be conveniently lifted, and the eave of the historic building can be stably supported and reinforced;

the worm rod and the worm wheel on the rotating shaft are arranged, so that the included angle between the upper block body and the lower block body can be further adjusted, and the rotation of the screw rod is further limited, so that the sliding block is not easy to drive the screw rod to rotate in the mounting groove due to the pressure of the ancient building eave, and the adjustable cushion block and the reinforcing cylinder can more stably support the ancient building eave;

through the limiting block and the limiting groove which are provided with the T-shaped structures, the sliding block can be limited, so that the sliding block can slide on the screw rod more stably.

Drawings

FIG. 1 is a schematic view of the overall structure of the reinforcing structure of the present application supported on an ancient building;

FIG. 2 is a schematic view of the overall structure of the reinforcement structure of the present application;

FIG. 3 is an enlarged schematic view of the structure of section A of FIG. 2;

FIG. 4 is a schematic view of the overall construction of the adjustment member of the present application;

fig. 5 is a schematic view showing the structure of an adjustable spacer block made in the wedge groove.

Description of reference numerals: 1. an eave; 2. reinforcing the column body; 3. an adjustable cushion block; 31. an upper block body; 311. a wedge-shaped groove; 32. a lower block body; 321. mounting grooves; 322. a limiting groove; 323. a dial scale; 33. a rotating shaft; 331. a turbine; 4. an adjustment member; 41. a screw rod; 411. a scroll bar; 42. a slider; 421. a protrusion; 422. a limiting block; 423. a flexible mat.

Detailed Description

The present application is described in further detail below with reference to figures 1-5.

The embodiment of the application discloses integral reinforcement structure of ancient building.

Referring to fig. 1 and 2, a whole reinforced structure of ancient building is including being used for strutting the reinforcement cylinder 2 and the adjustable cushion 3 of jacking to ancient building eave 1, and vertical the placing in subaerial and the high adaptability who consolidates cylinder 2 of reinforcement cylinder 2 is adjusted, and adjustable cushion 3 passes through component fixed connection such as bolt and steel nail in 2 tops of reinforcement cylinder, and adjustable cushion 3 cooperatees with reinforcement cylinder 2, carries out the pad-up support to ancient building eave 1.

Referring to fig. 2 and 3, the adjustable cushion block 3 includes an upper block 31 and a lower block 32, the upper block 31 and the lower block 32 are rectangular blocks with the same specification, a rotating shaft 33 is disposed between the upper block 31 and the lower block 32, the rotating shaft 33 is rotatably mounted at one side edge of the lower block 32, one side edge of the upper block 31 is rotatably connected to the lower block 32 through the rotating shaft 33, and an adjustable included angle is formed between the upper block 31 and the lower block 32; the upper block 31 is rotated around the rotating shaft 33, so that the included angle between the upper block 31 and the lower block 32 can be adjusted.

In order to conveniently adjust the included angle between the upper block body 31 and the lower block body 32 and maintain the adjusted included angle unchanged, an adjusting piece 4 for controlling the upper block body 31 to be close to or far away from the lower block body 32 is further arranged between the upper block body 31 and the lower block body 32.

Referring to fig. 3 and 4, the adjusting member 4 includes a screw rod 41 and a sliding block 42, an inwardly recessed linear mounting groove 321 is formed in the upper surface of the lower block 32, the length direction of the mounting groove 321 is perpendicular to the axis of the connecting shaft, the screw rod 41 is mounted in the mounting groove 321, the axis of the screw rod 41 is consistent with the axis of the mounting groove 321, and two ends of the screw rod 41 penetrate through two sidewalls of the mounting groove 321 in the linear direction on the lower block 32 and are rotatably connected with the lower block 32; the sliding block 42 is a rectangular block with a block-shaped protrusion 421 at the lower part, the sliding block 42 is located between the upper block body 31 and the lower block body 32, the sliding block 42 is sleeved on the screw rod 41 through the block-shaped protrusion 421 at the lower part and is in threaded connection with the screw rod 41, two side walls of the block-shaped protrusion 421 at the lower part of the sliding block 42 along the width direction of the installation groove 321 are abutted with two side walls of the installation groove 321 in the upper installation groove 321 of the lower block body 32 along the width direction of the installation groove 321, and the lower surface of the upper block body 31 is adapted to be abutted with the upper part of the sliding block 42.

When the upper block body 31, the lower block body 32, sliding block 42 and lead screw 41 are all in the natural state, the upper block body 31 is put on the sliding block 42 because of gravity, and the contact position of the upper block body 31 and the sliding block 42 is a side edge of the sliding block 42, when the lead screw 41 rotates, the sliding block 42 is provided with the driving force for rotating around the lead screw 41, the block-shaped protrusion 421 at the lower part of the sliding block 42 is matched with the lower block body 32 and the installation groove 321, the rotation of the sliding block 42 is limited, the sliding block 42 slides around the lead screw 41 in a straight line, so that the sliding block 42 can only be close to or far away from the rotating shaft 33 along with the rotating straight line of the lead screw 41, the upper block body 31 is lifted or lowered on the lower block body 32, and the adjustment of the included angle between the upper block body 31 and the lower block body 32 is realized more conveniently.

Further, referring to fig. 3 and 4, in order to enable the upper block 31 to better overlap the sliding block 42, a flexible pad 423 is further connected to the upper portion of the sliding block 42 above the lower block 32, and the lower surface of the upper block 31 is adapted to abut against the flexible pad 423; flexible pad 423 can be between last block 31 and sliding block 42, enlarges the supporting area of sliding block 42 to last block 31 for sliding block 42's stress position converts a side into by a side, and more stable supports last block 31, makes bearing ancient building eaves 1's that reinforced structure can be better gravity and pressure.

In order to enable the sliding block 42 to better adapt to and accept the gravity and the pressure of the upper block body 31 and the ancient building eave 1 and prevent the sliding block 42 from forcing the screw rod 41 to rotate due to the overlarge gravity and pressure and further prevent the sliding block 42 from moving relative to the rotating shaft 33, referring to fig. 3 and 4, a turbine 331 and a turbine rod 411 for further limiting the rotation of the screw rod 41 are further arranged between the rotating shaft 33 and the screw rod 41.

The worm 331 is sleeved and fixedly connected to the middle of the rotating shaft 33, the worm 411 is fixedly connected to one end of the screw rod 41 close to the rotating shaft 33, the worm 411 is coaxially arranged with the screw rod 41 and perpendicular to the rotating shaft 33, the worm 411 is located below the rotating shaft 33 and engaged with the worm 331, and the worm 331 is fixedly connected to the lower portion of the upper block 31.

Referring to fig. 3 and 4, when the screw rod 41 is rotated, the turbine 331 can coaxially rotate along with the screw rod 41, so as to drive the turbine 331 to rotate, the turbine 331 drives one side of the upper block 31, which is far away from the rotating shaft 33, to approach or be far away from the lower block 32 around the rotating shaft 33, and an included angle between the upper block 31 and the lower block 32 is adjusted; in this in-process, turbine 331 and scroll bar 411 carry out dual regulation in cooperation lead screw 41 and sliding block 42 to the contained angle between last block 31 and the lower block 32, better rotation to lead screw 41 has carried on spacingly, make sliding block 42 difficult self bearing and pressure-bearing when lead screw 41 no longer rotates great and force lead screw 41 to take place to rotate, and then take place to remove in mounting groove 321, make adjustable cushion 3 and reinforcement cylinder 2 can be more stable support ancient building eave 1.

Furthermore, a dial 323 is arranged on the outer wall of one side of the lower block body 32 far away from the rotating shaft 33, one end of the screw rod 41 far away from the rotating shaft 33 is positioned in the middle of the dial 323, and the middle point of the dial 323 is positioned on the axis of the screw rod 41; the worm 411 is combined with the screw rod 41, when the screw rod 41 rotates for one circle, the worm 411 and the screw rod 41 rotate for one circle coaxially, the worm wheel 331 rotates for half a circle around the rotating shaft 33 along with the worm 411, and then the upper block 31 is driven to rotate for 180 degrees around the rotating shaft 33.

Referring to fig. 3 and 4, the reading on the scale 323 is 0-360 °, and by observing the reading on the scale 323, a worker can conveniently control the rotation angle of the lead screw 41, and when the lead screw 41 rotates by 2 °, the turbine 331 can drive the upper block 31 to rotate by 1 ° around the rotation shaft 33 along with the worm 411; in this process, slider 42 carries out rectilinear movement on lead screw 41 along with the rotation of lead screw 41, and slider 42 is close to or keeps away from axis of rotation 33, and when the contained angle between last block 31 and the lower block 32 was less than 90, goes up block 31 and can take all the time on slider 42, and slider 42 can be better support last block 31 and the ancient building eaves 1 that supports on the last block 31.

In order to make the upper block 31 also be capable of adaptively supporting the historic building eave 1 with the inclination angle of 0 degree, referring to fig. 3 and 5, a wedge-shaped groove 311 is further formed in one side of the upper block 31 close to the lower block 32, the upper part of the sliding block 42 is slidably connected in the wedge-shaped groove 311, and the groove depth of the wedge-shaped groove 311 is gradually reduced from one side far away from the rotating shaft 33 to one side close to the rotating shaft 33; when the sliding block 42 slides to the end part of the mounting groove 321 far away from the rotating shaft 33, the lower surface of the upper block 31 is suitable for abutting against the lower block 32, the upper surface and the lower surface of the upper block 31 and the upper surface and the lower surface of the lower block 32 are horizontal planes, and the upper block 31 can better support the ancient building eave 1 with the inclination angle of 0 degree.

Referring to fig. 3 and 4, the lower block 32 is further provided with a limiting groove 322 for further limiting the sliding of the sliding block 42 at two sides of the mounting groove 321 along the linear direction of the mounting groove 321, the limiting groove 322 is a T-shaped groove, the lower part of the sliding block 42 is convexly provided with a T-shaped limiting block 422 adapted to be matched with the T-shaped limiting groove 322, the cross-sectional area of one side of the limiting block 422 away from the sliding block 42 is larger than that of one side of the limiting block 422 close to the sliding block 42, and the limiting block 422 is slidably connected in the limiting groove 322; through stopper 422 and spacing groove 322 cooperation, the slider slides on lead screw 41 more steadily, and then can be better support the reinforcement to last block 31 and the ancient building eave 1 that supports on the block 31.

The implementation principle of the integral reinforcing structure of the ancient building in the embodiment of the application is as follows: when needs support the reinforcement to ancient building eave 1, at first measure the contained angle between ancient building eave 1 and the horizontal plane, according to surveying the contained angle number, rotate lead screw 41 according to the reading on calibrated scale 323, make the contained angle between last block 31 and the lower block 32 unanimous with surveying the contained angle number, then heighten and consolidate cylinder 2, make and drive adjustable cushion 3 and rise, adaptability supports ancient building eave 1, it is less to go up the clearance between block 31 and the ancient building eave 1, it is better to consolidate the effect with the support of adjustable cushion 3 to the ancient building to consolidate the cylinder 2.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides an ancient building's whole reinforced structure, includes and is used for strutting reinforcement cylinder (2) of jacking to ancient building eave (1), it is subaerial that reinforcement cylinder (2) are vertical to be placed in its characterized in that: the top of the reinforcing column body (2) is connected with an adjustable cushion block (3), the adjustable cushion block (3) comprises an upper block body (31) and a lower block body (32), one side of the upper block body (31) is rotatably connected to the lower block body (32), and an adjustable included angle is formed between the upper block body (31) and the lower block body (32); an adjusting piece (4) is arranged between the upper block body (31) and the lower block body (32), and the adjusting piece (4) is used for controlling the upper block body (31) to be close to or far away from the lower block body (32).

2. The integral reinforced structure of an ancient building according to claim 1, wherein: the adjusting piece (4) comprises a screw rod (41) and a sliding block (42), a linear installation groove (321) is formed in the upper surface of the lower block body (32), the length direction of the installation groove (321) is perpendicular to a connecting line of the upper block body (31) and the lower block body (32), the axis direction of the screw rod (41) is parallel to the length direction of the installation groove (321), and the screw rod (41) penetrates through two side walls in the linear direction in the installation groove (321) in the lower block body (32) and is installed in the installation groove (321); sliding block (42) are located between last block (31) and lower block (32), just sliding block (42) lower part cover is established and threaded connection is on lead screw (41), sliding block (42) lower part and mounting groove (321) of lower block (32) are along width direction's both sides wall looks butt, the lower surface of going up block (31) is suitable for the butt in sliding block (42) upper portion.

3. The integral reinforcement structure of an ancient building according to claim 2, wherein: the connecting part of the upper block body (31) and the lower block body (32) is also provided with a rotating shaft (33), the upper block body (31) and the lower block body (32) are rotatably connected through the rotating shaft (33), the screw rod (41) is perpendicular to the rotating shaft (33), and the rotating shaft (33) is positioned above the screw rod (41); the rotating shaft (33) is provided with a turbine (331) which is sleeved at the position where the rotating shaft (33) is perpendicular to the screw rod (41) and fixedly connected with the turbine (331), one end, close to the rotating shaft (33), of the screw rod (41) is connected with a worm (411), the worm (411) and the screw rod (41) are coaxially arranged, the worm (411) is meshed with the turbine (331) and connected with the lower portion of the upper block body (31) in a fixed mode.

4. The integral reinforcement structure of an ancient building according to claim 3, wherein: install calibrated scale (323) on block (32) keep away from one side outer wall of axis of rotation (33) down, lead screw (41) keep away from the one end of axis of rotation (33) and are located calibrated scale (323), calibrated scale (323) mid point is located the axis of lead screw (41), scroll (411) combine together with lead screw (41), scroll (411) rotate the round, turbine (331) revolve axis of rotation (33) and rotate the half-turn.

5. The integral reinforcement structure of an ancient building according to any one of claims 2 to 4, wherein: a wedge-shaped groove (311) is further formed in one side, close to the lower block (32), of the upper block (31), the upper portion of the sliding block (42) is suitable for being connected into the wedge-shaped groove (311) in a sliding mode, and the depth of the wedge-shaped groove (311) is gradually reduced from one side, far away from the rotating shaft (33), to one side, close to the rotating shaft (33); when the sliding block (42) slides to one end part of the mounting groove (321) far away from the rotating shaft (33), the lower surface of the upper block body (31) is suitable for abutting against the lower block body (32), and the upper surface and the lower surface of the upper block body (31) and the upper surface and the lower surface of the lower block body (32) are both horizontal planes.

6. The integral reinforcement structure of an ancient building according to claim 5, wherein: the upper portion of the sliding block (42) is connected with a flexible pad (423), and the lower surface of the upper block body (31) is suitable for abutting against the flexible pad (423).

7. The integral reinforcement structure of an ancient building according to claim 5, wherein: spacing groove (322) have still been seted up on block (32) upper portion position in mounting groove (321) both sides down, sliding block (42) lower part protrusion is provided with stopper (422), stopper (422) sliding connection is in spacing groove (322).

8. The integral reinforced structure of an ancient building according to claim 7, wherein: the limiting block (422) is a T-shaped block, the cross-sectional area of one side, away from the sliding block (42), of the limiting block (422) is larger than that of one side, close to the sliding block (42), of the limiting block (422), and the limiting groove (322) is a T-shaped groove corresponding to the T-shaped block.

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