CN216688983U - Prefabricated assembled invisible bent cap - Google Patents

Abstract

The utility model discloses a prefabricated invisible capping beam which is used for building a fully prefabricated small box girder type invisible capping beam structure system and comprises a hidden capping beam body, wherein the hidden capping beam body is formed by splicing a plurality of hidden capping beam prefabricated sections, two adjacent hidden capping beam prefabricated sections are spliced in a male-female tooth embedding mode, and meanwhile, all the hidden capping beam prefabricated sections are connected into a whole through a transverse bridge-direction prestressed steel beam which is tensioned and anchored; the hidden cover beam prefabricated segment is arranged on two end faces in the bridge direction, at least one end face is provided with a small box beam splicing seam notch capable of being embedded with the end part of a prefabricated small box beam, and a plurality of rows of splicing seam notch convex shear-resistant stirrups are distributed in the small box beam splicing seam notch along the vertical direction. Therefore, the cost for building the fully-prefabricated small box girder type invisible bent cap structure system can be effectively reduced.

Description

Prefabricated assembled invisible bent cap

Technical Field

The utility model relates to a prefabricated invisible bent cap, and belongs to the field of civil engineering bridge design and engineering construction.

Background

Under the promotion of national strategic guidance and the requirements of society and industry development, the bridge construction technology is developing towards the direction of assembly, industrialization and standardization. At present, the development of the 'prefabrication and assembly' of domestic concrete beam bridges mainly has 3 directions:

1) the bridge span upper structure adopts a prefabricated small box girder to replace a cast-in-place box girder

In urban expressway construction, the replacement of cast-in-place box girders by prefabricated small box girders has become a common consensus of all construction parties. On one hand, under the same span, the concrete consumption of the prefabricated small box girder is only 50% of that of the cast-in-place box girder; in a soft soil area, the construction cost of the scheme of prefabricating the small box girder is less than 75 percent of that of a cast-in-place box girder (the engineering quantity of a lower part structure is reduced, and the on-site foundation treatment cost is saved), so that the method has remarkable economic benefit; on the other hand, with the popularization and application of UHPC high-performance concrete, the width of the splicing seam of the prefabricated small box girder is strictly controlled from 50mm in the past and gradually widened to 300mm, so that the scheme of the prefabricated small box girder can meet the construction requirements of a wide section and a bent section by adjusting the width of the splicing seam.

Taking Ningbo city as an example, the 2011 completed airport road viaduct has a main line upper structure which adopts a cast-in-place box girder structure; 75% of the upper structures of the south ring and the north ring which are completed in 2015 adopt a prefabricated small box girder structure or a prefabricated hollow plate girder, and only a curve section, a widening section and a ramp connecting section adopt cast-in-situ box girders; the engineering of airport road overhead south extension started in 2017, western flood large bridge connection and the western city south extension started in 2018 have the advantages that the small prefabricated box girders (the curve section, the widening section and the ramp connecting section are all prefabricated structures) are adopted in 95% of the whole line, and only the section with limited passing clearance is the cast-in-place box girder.

2) The bridge span superstructure adopts a 'short-line method' segment prefabricated assembly beam to replace a cast-in-place box beam

Since the 21 st century, the adoption of the segment prefabrication and assembly technology of the 'short line method' is gradually tried in China, and the segment prefabrication and assembly technology is gradually popularized and applied in major projects, as shown in the specification. The segment prefabrication and assembly technology by the stub method basically solves the problem of factory prefabrication of a bridge span structure, and each prefabricated part is fused into a whole only by adopting 'external prestress' and 'cementing shear key' on site. Over the course of more than 20 years, there has been a move from a conventional single-box, single-chamber cross-section to a wide single-box, multi-chamber cross-section.

3) The bridge substructure (pier stud and capping beam) adopts finished large-tonnage prefabricated components

The integral prefabrication and assembling technology of the bridge pier columns is initially applied to the construction of a cross-sea bridge, namely the integral manufacture of the pier columns is completed on land, the pier columns are transported to a bridge position through a floating pontoon, and finally the pier columns are installed in place at one time by means of the large-tonnage hoisting capacity of a floating pontoon crane.

In nearly 10 years, with the great improvement of the construction requirements of the urban expressway elevated construction site (dust control, noise control, night light control, traffic diversion and transformation restriction and the like), the maintenance cost of the construction site rises due to the water rise. In part of overhead projects built on the existing roads, the construction of pier columns and capping beams by adopting a prefabrication and assembly technology is gradually tried, namely, the integral prefabrication of the upright columns or the capping beams is completed in a factory, and the erection is completed by adopting a large-tonnage crane on the spot.

At present, similar engineering construction cases are adopted in Shanghai, Zhejiang, Jiangsu, Guangdong, Shandong, Hunan, Sichuan and other provinces.

When the upright posts or the bent caps are integrally prefabricated and assembled, the sizes of the components are set to be contradictory.

On one hand, the larger the single component is, the stronger the structural integrity is, the fewer the on-site abutted seams are, and the structural performance is closer to that of a cast-in-place structure; on the other hand, as the size of the component increases, the weight of the structure increases accordingly, and 3 challenges are faced:

1) the requirement on the bearing capacity of the foundation of a construction area is increased, for example, a member of 40m3 (a column of 2.5m multiplied by 6.4m or 1/3 common capping beams) is taken as an example, the weight of a single body reaches 100 tons, 250-300 tons of hoisting equipment (determined according to the working environment) are needed, and the bearing capacity of the foundation is not lower than 150 kPa; and the weight of the single body of the 75m3 component (half width cover beam) reaches 200 tons, 500 tons of hoisting equipment (the upper limit of the conventional hoisting equipment and the hoisting equipment at the higher level are not all provided in provinces) is required, and the foundation bearing capacity is required to be improved to 250 kPa.

2) The difficulty of component transportation is improved: the size of the prefabricated part is also limited by road transportation (the width is multiplied by the height is less than or equal to 3m multiplied by 3 m), and the larger the volume is, the higher the transportation difficulty is.

3) Reduced versatility of factory manufacturing: the larger the size of the member is, the higher the matching requirement of a manufacturing factory is (such as the specification of a portal crane and the scale of a manufacturing field), and meanwhile, the universality of the matching template is weaker (the prefabricated member is produced in batch, a wood template is not selected, and the customization property of a steel template is stronger), so that the cost advantages of the prefabricated member and a cast-in-place member are reduced.

The first two challenges of the above analysis often push up the construction costs of the stud & capping beam components-this makes such prefabricated construction techniques an even more economical choice between "urban civilized construction requirements" and "engineering schedules", the larger the prefabricated components, the more significant the economic disadvantages of the prefabricated assembled components.

Therefore, the core and the key for the popularization and the application of the technology are to seek the efficient prefabrication and assembly of the small-volume components.

The small prefabricated box girder system is mature in construction process, and a production line and a bridge girder erection machine of a prefabrication factory can be widely applied to various bridge projects, but are limited by the larger structural height (the prefabricated girder and the bent cap) and cannot be used in a clear height limited area.

One solution is to design the bent cap into an inverted T shape, and lay the prefabricated small box girder on a bracket to form a semi-hidden prefabricated small box girder system. At the moment, the upper bridge span structure only maintains a simple support system, which is influenced by the middle section bulge of the inverted T-shaped cover beam, the prefabricated small box beam only maintains the mode that the bridge deck is continuous and the structure is simple in the area, and under the same span, the raw material consumption of the simple support beam is greatly increased compared with that of the continuous system: the consumption of the steel bars is increased by 40%, the consumption of the concrete is increased by 27%, the consumption of the prestressed steel bundles is increased by 32%, and the quantity of the expansion joints is increased by 200% (when the structure is discontinuous, the continuous bridge deck is easy to damage). In addition, the simply supported beam is a static system, is influenced by uneven settlement of a foundation, is easy to break at the end part, and seriously influences the driving comfort, namely the phenomenon of 'jumping' needs to be strictly controlled when the urban expressway overhead with the speed of 80km/h is designed, and the popularization and the application of the system are seriously restricted.

Another solution is a hidden beam structure system. The prefabricated small box girder and the cover girder are arranged in the same plane, and the problem of net height of the prefabricated small box girder is solved. And the hidden cover beam structure system adopts a process of erecting the prefabricated small box beam and pouring the concrete hidden cover beam during construction, so that the prefabrication of the main body part of the concrete beam type bridge under the condition of effective clearance is met.

However, the above construction method has the following 3 cost concerns:

1) the temporary support measures are invested greatly: the weight of the prefabricated small box girder is larger, the span diameter of the prefabricated small box girder is usually 26-35 m, the weight of a single body is about 75-120 tons, 8-12 prefabricated girders are usually arranged in the direction of an overhead transverse bridge of a city, the total weight is over 2500 tons, a temporary supporting structure of the prefabricated small box girder is comparable to that of a permanent cover girder, and the measure investment is large;

2) the prefabricated beam is erected with high difficulty: in order to ensure the continuity of a structural system, longitudinal steel bars at the end parts of two ends of a prefabricated small box girder extend out by 1.2-1.5 m (namely 1/2 width of a midspan hidden cover girder or 80% width of the hidden cover girder at the end part), the positions of the part of steel bars and a temporary support system are in conflict (along a bridge direction projection plane, a temporary support structure is positioned in the range of the prefabricated small box girder), so that the simplest 'inside-span beam raising' process of the prefabricated small box girder cannot be practiced, if a 'rear-span beam feeding' process is adopted, a bridge erecting machine and rear-span hoisting equipment (the rear-span beam feeding process is also required to be provided with hoisting equipment to lift the prefabricated small box girder to a high erecting plane) need to wait for the pouring time of the hidden cover girder (usually not less than 2 months), and the economic benefit is very low; if an automobile crane erecting process (double-crane lifting) is adopted, the number of small box girders which can be erected by a single supporting leg of the hoisting equipment is limited under the influence of the extending steel bars at two ends (see the hidden cover girder construction scheme for details); if a crawler crane erection process (single machine hoisting and crawler movement) is adopted, higher requirements are put on the foundation bearing capacity of the temporary road on the construction site (400-ton crawler crane operation);

3) the cast-in-place hidden cover beam has high reinforcement ratio: although the cast-in-place hidden cover beam is provided with intensive transverse bridge-direction prestressed steel bundles, a large number of common steel bars are still configured at the design level at the present stage to deal with uncertain complex multidirectional stress effects, namely the design calculation research of the prefabricated small box beam hidden cover beam structure system is relatively less compared with the conventional structure system, compared with the cast-in-place box beam, the hidden cover beam not only bears the end internal force of each prefabricated small box beam (mainly bending moment, shearing force and torque, but also locally mainly takes the positive stress and the shearing stress instead of being transmitted in the internal force mode), but also needs to resist the transverse load effect. Considering that the research on the mechanical characteristics of the joint of the small prefabricated box girder and the hidden cover girder is less (namely the mechanical property of the connection between the prefabricated structure and the cast-in-place structure), a design unit tends to configure a dense steel bar system more so as to ensure the effectiveness of the structure, and meanwhile, the bearing capacity and the normal use state reliability (crack control) of the structure are ensured.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects of the prior art, the utility model provides a prefabricated invisible bent cap which is constructed together with a prefabricated small box girder on site to form a fully prefabricated small box girder invisible bent cap structural system. Therefore, the utility model can expand the application range of the prefabricated small box girder structure system by utilizing the existing prefabricated small box girder production line, popularize the application of the prefabricated assembly structure at low cost, and has higher economic value and social benefit for the construction of urban bridges in China, particularly urban viaducts.

In order to achieve the technical purpose, the utility model adopts the following technical scheme:

a prefabricated invisible capping beam is used for building a fully prefabricated small box girder type invisible capping beam structure system and comprises a hidden capping beam body, wherein the hidden capping beam body is formed by splicing a plurality of hidden capping beam prefabricated sections, the two adjacent hidden capping beam prefabricated sections are spliced in a male-female tooth embedding mode, and meanwhile, the hidden capping beam prefabricated sections are connected into a whole through a transverse bridge-direction prestressed steel beam which is tensioned and anchored;

the hidden cover beam prefabricated segment is arranged on two end faces in the bridge direction, at least one end face is provided with a small box beam splicing seam notch capable of being embedded with the end part of a prefabricated small box beam, and a plurality of rows of splicing seam notch convex shear-resistant stirrups are distributed in the small box beam splicing seam notch along the vertical direction.

Preferably, the hidden cover beam prefabricated section comprises a hidden cover beam middle fulcrum section and can be spliced to form a hidden cover beam body arranged in a middle fulcrum area;

the hidden bent cap middle fulcrum section comprises a middle fulcrum bent cap middle section body and a middle fulcrum bent cap end section body;

the two end surfaces in the bridge direction of the middle section body of the middle fulcrum bent cap/the end section body of the middle fulcrum bent cap are both provided with bent cap joint surfaces which are correspondingly a first bent cap joint surface and a second bent cap joint surface; the middle section body of the middle fulcrum bent cap/the end section body of the middle fulcrum bent cap are provided with prestressing ducts along the bridge direction through the first bent cap joint surface and the second bent cap joint surface;

the two end surfaces of the middle section body of the middle fulcrum bent cap in the transverse bridge direction are respectively provided with a bent cap section splicing surface, and correspondingly comprise a first bent cap section splicing surface and a second bent cap section splicing surface; the middle section body of the middle fulcrum bent cap penetrates through the splicing surface of the first bent cap section and the splicing surface of the second bent cap section to form a transverse bridge-direction prestressed steel beam pore channel;

the end face of the middle fulcrum bent cap end section body, which is positioned in two end faces in the transverse bridge direction, only positioned on the inner side is provided with a bent cap section splicing face;

the capping beam joint surface is provided with a small box girder joint notch penetrating through the top surface of the corresponding hidden capping beam prefabricated section;

the splicing surface of the first bent cap section is arranged away from the middle point of the spliced hidden bent cap, and a plurality of concave tooth blocks are arranged on the splicing surface of the first bent cap section;

the splicing surface of the second bent cap section is arranged close to the middle point of the spliced hidden bent cap, and the splicing surface of the second bent cap section is provided with an outer convex tooth block; the positions of the concave tooth blocks on the two sides of the middle section body of each middle fulcrum bent cap correspond to the positions of the convex tooth blocks;

the transverse bridge-direction prestressed steel beam channels are arranged in a staggered manner with the convex tooth blocks/concave tooth blocks;

transverse bridge-direction prestress steel beams are pre-buried in the end section bodies of the middle fulcrum bent caps, the end section bodies of the middle fulcrum bent caps are positioned on the splicing surfaces of the bent caps in the transverse bridge direction, and convex tooth blocks matched with the concave tooth blocks corresponding to the middle section bodies of the middle fulcrum bent caps are arranged; each transverse bridge-direction prestressed steel beam pore passage corresponds to a transverse bridge-direction prestressed steel beam pre-embedded in the middle fulcrum bent cap end section body.

Preferably, the seam-splicing notch convex shear-resistant stirrups are distributed in three rows in the seam-splicing notch of the small box girder, and correspondingly comprise middle-row seam-splicing notch convex shear-resistant stirrups and side seam-splicing notch convex shear-resistant stirrups symmetrically arranged on two sides of the middle-row seam-splicing notch convex shear-resistant stirrups; convex shear-resistant stirrups of all rows of abutted seam notches are arranged along the height direction of the abutted seam notches of the small box girders.

Preferably, the convex shear-resistant stirrups of the abutted seam notches are U-shaped steel bars; the two ends of the U-shaped reinforcing steel bar are embedded in the groove bottom of the small box girder splicing groove opening, and the closed section of the U-shaped reinforcing steel bar protrudes outwards from the groove bottom of the small box girder splicing groove opening.

Preferably, the hidden cover beam prefabricated section comprises a hidden cover beam middle fulcrum section and can be spliced to form a hidden cover beam body arranged in a middle fulcrum area;

the hidden bent cap edge fulcrum section comprises an edge fulcrum bent cap middle section body and an edge fulcrum bent cap end section body;

the structure of the middle section body of the side fulcrum bent cap in the transverse bridge direction is consistent with the structure of the middle section body of the middle fulcrum bent cap in the transverse bridge direction;

the structure of the end section body of the side fulcrum bent cap in the transverse bridge direction is consistent with the structure of the end section body of the middle fulcrum bent cap in the transverse bridge direction;

the hidden cover beam edge fulcrum section is positioned in two end faces along the bridge direction, and the end face close to the middle fulcrum area is provided with a cover beam joint surface.

Preferably, the concave tooth blocks are distributed into 3 rows on the splicing surface of the first bent cap section and correspond to a first row, a second row and a third row of concave tooth blocks, the first row, the second row and the third row of concave tooth blocks respectively comprise a plurality of concave tooth blocks distributed along the height direction of the splicing surface of the first bent cap section, the first row of concave tooth blocks is positioned in the middle direction of the splicing surface of the first bent cap section, and the second row and the third row of concave tooth blocks are symmetrically distributed on two sides of the first row of concave tooth blocks;

the convex tooth blocks are distributed into 3 rows on the splicing surface of the second cover beam section and are correspondingly provided with a first row of convex tooth blocks, a second row of convex tooth blocks and a third row of convex tooth blocks, the first row of convex tooth blocks, the second row of convex tooth blocks and the third row of convex tooth blocks respectively comprise a plurality of convex tooth blocks distributed along the height direction of the splicing surface of the first cover beam section, the first row of convex tooth blocks are positioned in the middle direction of the splicing surface of the first cover beam section, and the second row of convex tooth blocks and the third row of convex tooth blocks are symmetrically distributed on two sides of the first row of convex tooth blocks;

in each hidden cover beam middle section, the positions of the concave teeth in the first row of concave teeth all correspond to the positions of the convex teeth in the first row of convex teeth, the positions of the concave teeth in the second row of concave teeth all correspond to the positions of the convex teeth in the second row of convex teeth, and the positions of the concave teeth in the third row of concave teeth all correspond to the positions of the convex teeth in the third row of convex teeth.

Compared with the prior art, the technical scheme of the utility model has the following advantages:

1. the prefabricated assembled invisible capping beam has the advantages that the prefabricated sections of the invisible capping beam are prefabricated in an industrial mode, and then the required invisible capping beam is assembled on site, so that the prefabricated assembled invisible capping beam has the following advantages compared with a cast-in-place invisible capping beam:

1-1, the erection mode of firstly covering the beam (hidden covering beam) and then prefabricating the beam (prefabricated small box beam) can be adopted, so that a temporary support system required to be built in the construction process of the hidden covering beam structural system is simplified, and the cost is effectively saved.

1-2, in the construction process, the finished assembled invisible bent cap can be used as a temporary support, so that the problem of large-scale temporary measure investment is solved.

1-3, adopting a fully prefabricated assembled joint, eliminating reinforcing steel bars at the end part of a small box girder, and adopting the most economical 'span-inside beam lifting' process for hoisting;

1-4, the hidden cover beam also adopts a prefabricated assembled structure, defines a mechanical transmission path and uses materials on the cutting edge.

2. The prefabricated assembled invisible capping beam can form a mosaic shear-resistant hoop system together with the small box girder end convex shear-resistant hoop arranged at the girder end of the prefabricated small box girder due to the arranged seam-splicing notch convex shear-resistant hoop, the interface shear-resistant bearing capacity between the prefabricated segment of the invisible capping beam and the prefabricated small box girder is improved through the coherent arrangement of the shear-resistant hoop, and the interface strength between the prefabricated segment of the invisible capping beam and the prefabricated small box girder is effectively ensured by combining UHPC (ultra high performance concrete) crack pouring.

Drawings

FIG. 1 is a schematic structural diagram of a fully prefabricated small box girder type invisible bent cap structural system according to the utility model;

in FIG. 1: 1-a conventional section of a small box girder; 2-small box girder end solid section; 3-hiding the middle fulcrum section of the bent cap; 4-UHPC filling layer; 5-the middle fulcrum bent cap end segment;

FIG. 2 is a schematic structural view of a conventional section of the mini-box beam of FIG. 1;

in the figure: 1-1, a conventional section body; 1-2, spanning an internal prestressed steel bundle by a box girder;

FIG. 3 is a schematic structural view of a solid end section of the mini-box girder of FIG. 1;

FIG. 4 is a schematic structural view of another direction of the end solid section of the box girder;

in fig. 3 and 4: 2-1, a beam end solid section body; 2-2, splicing and sewing surfaces of box girders; 2-3, convex shear-resistant stirrups at the beam ends of the small box beams; 2-4, coupling prestressed ducts among the segments; 2-5, a prestressed anchoring area; 2-6, spanning an internal prestressed steel strand pore channel of the box girder; 2-7, splicing surfaces of the box girders; 2-8, coupling and connecting the segments by using prestressed steel bundles; 2-9, coupling the tension end of the steel bundle for connection;

FIG. 5 is a schematic structural view of the middle section body of the mid-pivot bent cap depicted in FIG. 1 (the prestressed tendon channels are not shown);

FIG. 6 is a schematic view of the construction of the middle section body of the mid-pivot bent cap in another orientation;

in fig. 5 and 6, 3-1, the first lid beam segment splice plane; 3-2, a first bent cap joint surface; 3-3, splicing and sewing the notch with the small box girder; 3-3-1, 3-4, transverse bridge direction prestressed steel bundle pore paths, and the abutted seam notch convex shear resistant stirrups; 3-5, an inner concave tooth block; 3-6, a middle section body of the middle fulcrum bent cap; 3-7, convex tooth blocks;

FIG. 7 is a schematic structural view of the body of the end segment of the mid-pivot bent cap depicted in FIG. 1 (without the pre-stressed steel-bundle channels shown);

FIG. 8 is a schematic view of the construction of the body of the end segment of the mid-pivot cap beam in another orientation;

in fig. 7 and 8: 5-1, a middle fulcrum capping beam end section body; 5-2, transverse bridge direction prestress steel bundles; 5-3, a small box girder splicing seam notch of the middle fulcrum bent cap end section body; 5-3-1, the seam rabbet convex shear-resistant hoop of the middle fulcrum bent cap end segment body; 5-4, a cap beam segment splicing surface of the cap beam segment body at the end part of the middle fulcrum cap beam; 5-5, an outer convex tooth block of the middle fulcrum bent cap end section body; 5-6, P anchor; 5-7, and a bent cap piece joint surface of the bent cap end section body of the middle pivot bent cap.

FIG. 9 is a schematic structural view of a fully precast mini-box girder type invisible bent cap structural system in a middle pivot area;

fig. 10 is a structural schematic diagram of the fully prefabricated small box girder type invisible bent cap structural system in the side pivot area.

FIG. 11 is a construction flow chart of the fully-prefabricated small box girder type invisible bent cap structural system.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. The following description of at least one exemplary embodiment is merely illustrative in nature and is in no way intended to limit the utility model, its application, or uses. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention. The relative arrangement of the components and steps, expressions and numerical values set forth in these embodiments do not limit the scope of the present invention unless specifically stated otherwise. Meanwhile, it should be understood that the sizes of the respective portions shown in the drawings are not drawn in an actual proportional relationship for the convenience of description. Techniques, methods, and apparatus known to those of ordinary skill in the relevant art may not be discussed in detail but are intended to be part of the specification where appropriate. In all examples shown and discussed herein, any particular value should be construed as merely illustrative, and not limiting. Thus, other examples of the exemplary embodiments may have different values.

Spatially relative terms, such as "above … …," "above … …," "above … … surface," "above," and the like, may be used herein for ease of description to describe one device or feature's spatial relationship to another device or feature as illustrated in the figures. It will be understood that the spatially relative terms are intended to encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures. For example, if a device in the figures is turned over, devices described as "above" or "on" other devices or configurations would then be oriented "below" or "under" the other devices or configurations. Thus, the exemplary term "above … …" can include both an orientation of "above … …" and "below … …". The device may also be oriented in other different ways (rotated 90 degrees or at other orientations).

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. In addition, for the purpose of convenience of description, the vertical direction, the transverse direction and the longitudinal direction are perpendicular to each other, and the two directions in the vertical direction are up and down directions respectively.

As shown in fig. 1 to 10, the fully prefabricated small box girder type invisible capping beam structure system of the present invention comprises a lower supporting structure and an upper structure disposed above the lower supporting structure, wherein the upper structure comprises a plurality of invisible capping beams disposed along a transverse bridge direction and a plurality of prefabricated small box girders disposed at two sides of each invisible capping beam and along a bridge direction; wherein:

the prefabricated small box girder comprises two parts, namely a small box girder conventional section 1 and a small box girder end solid section 2, as shown in figures 1 and 10.

The conventional section 1 of the small box girder, as shown in fig. 2, refers to a section of the cross section of the prefabricated small box girder, which is the same as the middle cross section of a general prefabricated small box girder span, and comprises a conventional section body 1-1, wherein a box girder span internal prestress steel bundle 1-2 extends outwards from the end of a web plate and the end of a bottom plate, in addition, the conventional section body 1-1 is provided with an operation manhole 1-1-1 with the diameter of 45cm in a top plate area, the center of the manhole 1-1-1 is 50-60 cm away from the edge of the conventional section body 1-1, and reinforcing steel bars are arranged on the periphery of the manhole 1-1-1.

The end solid section 2 of the small box girder is arranged at the end of the conventional section 1 of the small box girder, and the length of the end solid section is not less than 2m and not more than 4 m. The reason is that according to the holy-vern principle, the end stress is within 1 times of the beam height, the stress can be uniformly diffused, so the length of the small box girder end solid section 2 is not less than the beam height (1.6 m or 1.8 m), and the length of the small box girder end solid section 2 is not less than 2m in consideration of the range occupied by the end tooth block, the anchor plate and the like.

As shown in fig. 3-4, the small box girder end solid section 2 comprises a girder end solid section body 2-1, two end faces, namely a box girder splicing face 2-7 and a box girder splicing seam face 2-2, are oppositely arranged on the girder end solid section body 2-1 along the bridge direction, the box girder splicing face 2-7 is directly poured at the end part of the small box girder conventional section 1 and is integrally formed with the small box girder conventional section, and the box girder splicing seam face 2-2 is adjacent to the hidden cover girder. The box girder splicing seam surface 2-2 is divided into a shear resistant stirrup distribution area and a pre-stressed anchoring area 2-5. The prestressed anchoring area is divided into a web plate bundle anchoring area and a bottom plate bundle anchoring area. The web plate bundle anchoring area is provided with a web plate prestressed steel bundle pore canal for the web plate prestressed steel bundle to pass through, the bottom plate bundle anchoring area is provided with a bottom plate prestressed steel bundle pore canal for the bottom plate prestressed steel bundle to pass through, the web plate prestressed steel bundle and the bottom plate prestressed steel bundle jointly form a box girder inner-crossing prestressed steel bundle 1-2 shown in figure 2, and the web plate prestressed steel bundle pore canal and the bottom plate prestressed steel bundle pore canal jointly form a box girder inner-crossing prestressed steel bundle pore canal 2-6. Specifically, the prestressed anchoring areas all adopt embedded anchoring structures, the embedded anchoring structures can adopt occupied modules, and the manufacture of end templates (the occupied templates and the end templates can be simply connected or not connected and only contacted) is greatly simplified; because the prestressed anchoring area is the anchoring area of the prestressed steel strand, the installed end anchor plate and the spiral rib for anchoring are finished products, and are less influenced by the installation precision.

The anti-shear reinforcement structure is characterized in that the box girder splicing surface 2-2 of the small box girder end solid section 2 is provided with a shear-resistant reinforcement distribution area, the areas outside the pre-stressed anchoring area are provided with a plurality of rows of small box girder end convex anti-shear reinforcements 2-3 distributed at equal intervals, each row of small box girder end convex anti-shear reinforcements 2-3 comprise three U-shaped reinforcing steel bars distributed uniformly, two end parts of each U-shaped reinforcing steel bar are embedded in the small box girder end solid section 2, and the closed sections of the U-shaped reinforcing steel bars are arranged in the shear-resistant reinforcement distribution area of the small box girder end solid section 2 in an outward protruding mode. In addition, the small box girder end convex shear-resistant stirrups 2-3 are totally three rows, and comprise middle-row small box girder end convex shear-resistant stirrups and side small box girder end convex shear-resistant stirrups symmetrically arranged on two sides of the middle-row small box girder end convex shear-resistant stirrups. The outer convex shear-resistant stirrups at the beam ends of the middle row small box beams are positioned between the bottom plate prestressed steel bundles on the left side and the right side at the lower end pre-embedded positions of the shear-resistant stirrup distribution areas, and the outer convex shear-resistant stirrups at the beam ends of the side small box beams are adjacent to the positions of the bottom plate prestressed steel bundles at the lower end pre-embedded positions of the shear-resistant stirrup distribution areas.

In the utility model, in order to ensure that the distance from the inter-section coupling prestressed duct 2-4 to the inner edge of the prefabricated small box girder is not less than 100mm, the inter-section coupling prestressed duct 2-4 is only arranged at two sides of the convex shear resistant hoop at the end of the middle row of small box girder and is totally 6 (namely 6 are arranged on each row of the inter-section coupling prestressed ducts 2-4) from top to bottom, wherein the convex shear resistant hoops are distributed in a row between two adjacent rows of the small box girder ends. The prestressed steel beams for coupling connection between the sections are arranged in the coupling prestressed ducts between the sections, so that the prefabricated sections of the hidden cover beam are respectively connected with the solid sections at the end parts of the small box beams on the two longitudinal sides of the prefabricated sections of the hidden cover beam, and the arrangement of the coupling prestressed ducts between the sections ensures that the prestressed steel beams for coupling connection between the sections are distributed in the hollow projection range of the prefabricated small box beams. And web bundle anchoring areas are symmetrically arranged on two sides of the tooth block area, and a bottom plate bundle anchoring area is arranged on the lower side of the tooth block area.

The prestressed steel beams for coupling connection between the sections do not penetrate through the range of the convex shear-resistant stirrups at the beam end of the small box girder, so that the reliability of the convex shear-resistant stirrups at the beam end of the small box girder is ensured.

The coupling prestress pore channels between the sections adopt the principle of 'more distribution and less use', namely, the end part of a single prefabricated small box girder only needs to be provided with 4 holes, but 12 coupling prestress pore channels between the sections are reserved, so that the prefabricated small box girder can not be customized along with the characteristics of hidden cover girder sections in a factory manufacturing stage (the specification number of the factory prefabrication stage is reduced), and the product generalization is realized.

The small box girder end solid section corresponds to each box girder span internal prestressed steel strand, and a plurality of box girder span internal prestressed steel strand ducts which are respectively communicated with the web plate strand anchoring area and the bottom plate strand anchoring area are arranged, so that the box girder span internal prestressed steel strands can be anchored in the corresponding web plate strand anchoring area and the bottom plate strand anchoring area after being arranged along the corresponding box girder span internal prestressed steel strand ducts in the small box girder end solid section on site.

The web plate anchoring area is provided with three embedded anchoring structures along the height direction of the box girder splicing surface, each embedded anchoring structure is uniformly provided with a box girder internal-span prestressed steel strand pore passage, and the requirement of 5-degree inclined arrangement of the web plate prestressed steel strands can be met.

The bottom plate anchoring areas are respectively provided with an embedded anchoring structure at two sides of the bottom of the box girder splicing surface, and each embedded anchoring structure is uniformly provided with a box girder internal-span prestressed steel strand pore passage and can adapt to the arrangement of the prestressed steel strands of the bottom plate of the prefabricated small box girder.

The hidden cover beam is prefabricated in sections and is formed by splicing a plurality of sections of hidden cover beam prefabricated sections along the transverse bridge direction. The single hidden cover beam prefabricated section is matched with 1-2 prefabricated small box beams, the width of the single hidden cover beam prefabricated section is not more than 4.0m when the single prefabricated small box beam is matched, and the width of the single hidden cover beam prefabricated section is not more than 7.5m when the single hidden cover beam prefabricated section is matched with 2 prefabricated small box beams. The hidden cover beam prefabricated sections comprise two types, wherein one type is a hidden cover beam middle fulcrum section and can be spliced to form an assembled hidden cover beam arranged in a middle fulcrum area, and the other type is a hidden cover beam side fulcrum section and can be spliced to form an assembled hidden cover beam arranged in a side fulcrum area. The hidden cover beam prefabricated sections are similar in size and mainly cubic, and conditions are created for industrial manufacturing; on the other hand, the size of the hidden cover beam prefabricated section is small, the requirement on a prefabricated site is low, the manufacturing, transportation and hoisting cost is greatly reduced due to the miniaturization of the component, and the hidden cover beam prefabricated section has a prospect of large-scale popularization and application.

As shown in fig. 7 and 8, the hidden bent cap middle pivot segment includes a middle pivot bent cap middle segment body and a middle pivot bent cap end segment body; the hidden bent cap edge fulcrum section comprises an edge fulcrum bent cap middle section body and an edge fulcrum bent cap end section body.

As shown in fig. 5 and 6, the two end faces of the middle section body of the middle fulcrum bent cap/the end section body of the middle fulcrum bent cap in the bridge direction are both provided with bent cap joint surfaces, and are correspondingly provided with a first bent cap joint surface and a second bent cap joint surface; the middle section body of the middle fulcrum bent cap/the end section body of the middle fulcrum bent cap are provided with pre-stressed ducts along the bridge direction (not shown in the figure, but the pre-stressed ducts along the bridge direction are matched with coupling pre-stressed ducts among sections arranged on the prefabricated small box girder) which penetrate through the first bent cap joint surface and the second bent cap joint surface; the middle fulcrum bent cap middle section body is provided with bent cap section splicing surfaces at two end surfaces in the transverse bridge direction, the end surfaces are correspondingly provided with a first bent cap section splicing surface and a second bent cap section splicing surface, and the middle fulcrum bent cap middle section body is provided with a transverse bridge direction prestressed steel beam hole 5-2 by penetrating through the first bent cap section splicing surface and the second bent cap section splicing surface. The middle section body of the side fulcrum capping beam is positioned on two end faces in the transverse bridge direction, the structure of the middle section body of the side fulcrum capping beam is consistent with that of the middle section body of the middle fulcrum capping beam on the two end faces in the transverse bridge direction, the difference between the middle section body of the side fulcrum capping beam and the middle section body of the middle fulcrum capping beam is that the middle section body of the side fulcrum capping beam is positioned in the two end faces in the bridge direction, and the capping beam splicing surface is arranged on the end face only close to the middle fulcrum area.

And small box girder splicing notches 3-3 are arranged on the capping beam splicing surface and run through the top surfaces of the corresponding hidden capping beam prefabricated sections. The depth of the small box girder splicing seam notch 3-3 is 60mm, the distance H from the middle point of the bottom edge of the small box girder splicing seam notch 3-3 to the top edge is H +200mm, the outline shape of the small box girder splicing seam notch 3-3 is similar to the end shape of the prefabricated small box girder (the prefabricated small box girder is horizontally arranged, so the bottom edge is horizontal), and the small box girder splicing seam notch is pulled through only at the top according to the full width of the small box girder.

The small box girder splicing seam notches 3-3 are provided with splicing seam notch convex shear resistant stirrups 3-3-1, the splicing seam notch convex shear resistant stirrups 3-3-1 are also arranged in rows in the small box girder splicing seam notches 3-3, the quantity of the splicing seam notch convex shear resistant stirrups contained in each row of the splicing seam notch convex shear resistant stirrups 3-3-1 is just matched with the quantity of gaps between the adjacent two small box girder end convex shear resistant stirrups in each row of the small box girder end convex shear resistant stirrups 2-3, in other words, the quantity of the splicing seam notch convex shear resistant stirrups contained in each row of the splicing seam notch convex shear resistant stirrups 3-3-1 is less than that of the small box girder end convex shear resistant stirrups 2-3 in each row, and each splicing seam convex shear resistant stirrup in each row of the splicing seam notch convex shear resistant stirrups 3-3-1 can be embedded in each row of the small box girder convex shear resistant stirrups 2-3 And the convex shear resistant stirrups at the beam ends of two adjacent small box beams are arranged in the gap. In other words, in the splicing region formed by the prefabricated small box girder and the hidden cover girder, the convex shear-resistant stirrups at the girder end of the small box girder and the convex shear-resistant stirrups at the splicing groove opening are arranged in a staggered manner to form a shear-resistant stirrup system, so that the continuity of the stirrup system between the prefabricated small box girder and the hidden cover girder is ensured. And then, UHPC (ultra high performance concrete) is adopted as a pouring material of a splicing region formed by the small prefabricated box girder and the hidden cover girder, so that the small prefabricated box girder and the hidden cover girder are poured together to complete the connection of the small prefabricated box girder and the hidden cover girder. The transverse bridge-direction prestressed steel bundles which are arranged and tensioned in the transverse bridge-direction prestressed steel bundle pore passages mainly maintain the whole section in a pressed state, and have relatively small influence on the shearing-resistant bearing capacity of the interface. In addition, the convex shear resistant stirrups of the abutted seam notches are the same as the convex shear resistant stirrups at the small box girder ends, and U-shaped stirrups are also adopted.

The splicing surface of the first bent cap section is arranged away from the middle point of the spliced hidden bent cap, and a plurality of concave tooth blocks are arranged on the splicing surface of the first bent cap section; the concave tooth blocks are distributed into 3 rows on the splicing surface of the first bent cap section, the corresponding concave tooth blocks are first, second and third rows, the first, second and third rows of concave tooth blocks comprise a plurality of concave tooth blocks distributed along the height direction of the splicing surface of the first bent cap section, the first row of concave tooth blocks is positioned in the middle direction of the splicing surface of the first bent cap section, and the second and third rows of concave tooth blocks are symmetrically distributed on two sides of the first row of concave tooth blocks.

The splicing surface of the second bent cap section is arranged close to the middle point of the spliced hidden bent cap, and the splicing surface of the second bent cap section is provided with a plurality of convex tooth blocks to be matched with the concave tooth blocks of the fulcrum sections in the adjacent hidden bent cap. The outer convex tooth blocks are distributed into 3 rows on the splicing surface of the second cover beam section and correspondingly comprise a first row of outer convex tooth blocks, a second row of outer convex tooth blocks and a third row of outer convex tooth blocks, the first row of outer convex tooth blocks, the second row of outer convex tooth blocks and the third row of outer convex tooth blocks respectively comprise a plurality of outer convex tooth blocks distributed along the height direction of the splicing surface of the first cover beam section, the first row of outer convex tooth blocks are positioned in the middle direction of the splicing surface of the first cover beam section, and the second row of outer convex tooth blocks and the third row of outer convex tooth blocks are symmetrically distributed on two sides of the first row of outer convex tooth blocks.

In each middle fulcrum bent cap middle section body/side fulcrum bent cap middle section body, the positions of all the concave tooth blocks in the first row of concave tooth blocks correspond to the positions of all the convex tooth blocks in the first row of convex tooth blocks, the positions of all the concave tooth blocks in the second row of concave tooth blocks correspond to the positions of all the convex tooth blocks in the second row of convex tooth blocks, and the positions of all the concave tooth blocks in the third row of concave tooth blocks correspond to the positions of all the convex tooth blocks in the third row of convex tooth blocks.

And a transverse bridge-direction prestressed steel beam pore and a forward bridge-direction prestressed steel beam pore (not drawn in the attached drawing) are respectively arranged in the middle section body of the middle fulcrum bent cap. The transverse bridge direction prestressed steel beam pore ways are arranged between two adjacent rows of convex tooth blocks, transverse bridge direction prestressed steel beams are arranged in the transverse bridge direction prestressed steel beam pore ways, and the line shapes and the quantity of the transverse bridge direction prestressed steel beams are determined according to transverse bridge direction calculation analysis of the hidden cover beam. The transverse bridge steel beam in the hidden cover beam section and the prefabricated small box beam cross section allowed pore canal position are considered simultaneously along the bridge direction prestressed pore canal, and the total number of the pore canals with the diameter of not less than 4 and the diameter of 25mm (namely the area of the prestressed steel beam configured on the cross section is not less than 1680 mm)²). The splicing seam area (the end part of the small box girder and the end surface of the hidden cover girder in the bridge direction) adopts a non-clearance structure, and has a larger difference with the conventional segmental splicing technology, and necessary pre-stressed steel beams in the bridge direction (arranged in a pre-stressed pore channel in the bridge direction) are applied to the interface area, so that the beam bridge structural system is maintained in a full-section pressed state. One end of the pre-stressed steel beam along the bridge direction is connected with a tensioning end arranged at the end part of the solid section of the prefabricated small box girder at one side of the fulcrum section in the hidden cover girder, and the other end of the pre-stressed steel beam along the bridge direction is connected with a tensioning end arranged at the end part of the solid section of the prefabricated small box girder at the other side of the fulcrum section in the hidden cover girder.

The end section body of the middle fulcrum capping beam is positioned at two ends in the transverse bridge direction, a transverse bridge direction anchoring area is arranged at a position close to the end face of the outer side, a plurality of P anchors are embedded in the transverse bridge direction anchoring area, transverse bridge direction prestress steel bundles (transverse bridge direction prestress steel strands) are embedded in the end section body of the middle fulcrum capping beam directly through the P anchors, the inner side end face is consistent with the splicing surface structure of the second capping beam section of the middle fulcrum section of the hidden capping beam, and outer convex tooth blocks which are distributed in the same way are also arranged to be matched with the inner concave tooth blocks of the adjacent middle fulcrum section of the hidden capping beam.

According to the construction method, the transverse bridge-direction prestressed steel bundles are distributed and tensioned in the transverse bridge-direction prestressed steel bundle pore ways to improve the shearing resistance bearing capacity of the interface between the sections of the fulcrum areas in the two adjacent sections of hidden cover beams, and then the construction is finished by adopting a post-grouting process to seal the pipe. The pre-stressed channels in the direction along the bridge run through the splicing notches of the first small box girder and the second small box girder, correspond to partial pre-stressed steel beam channels arranged on the solid sections at the end parts of the small box girders, and are used for distributing pre-stressed steel beams for coupling connection among sections, so that the normal stress of the interface between the section of the fulcrum area in the hidden cover girder and the solid section at the end part of the small box girder is increased, and the shearing resistance bearing capacity of the interface is improved.

As shown in fig. 10, the edge fulcrum sections of the hidden bent cap are located at two ends along the bridge direction, and are provided with anchor areas along the bridge direction at positions close to the outer end face, and are provided with bent cap joint faces at end faces close to the inner side. A plurality of P anchors are pre-buried in the anchoring area along the bridge direction, so that the hidden cover beam edge fulcrum sections are directly connected with one ends of the prestress steel beams for coupling connection among the sections through the P anchors, and the other ends of the prestress steel beams for coupling connection are connected with the conventional section body tensioning ends of the adjacent prefabricated small box beams after sequentially penetrating through the hidden cover beam edge fulcrum sections and the small box beam end solid sections.

The arrangement mode of the end section body of the side fulcrum bent cap in the transverse bridge direction is consistent with that of the end section body of the middle fulcrum bent cap, and the description is omitted here.

The lower supporting structure comprises a bearing platform, two upright posts arranged on the bearing platform and a support arranged above each upright post. The upper structure is supported on the lower support structure by means of a support.

As a brand-new prefabricated assembled concrete beam bridge structure system, 3 sets of temporary systems need to be designed in the construction stage so as to ensure that the system is smoothly implemented:

1) in the assembly stage of the precast sections of the hidden cover beam sections, a first set of temporary support system needs to be designed, and the first set of temporary support system is detached after the hidden cover beam prestressed steel bundles are tensioned;

the first set of temporary supporting system adopts a steel pipe upright post and steel structure beam system, and the steel pipe upright posts are all positioned in a bearing platform area. The support beams of the first set of temporary support systems directly take over the hidden cover beam prefabricated sections.

2) Before the prefabricated small box girder is erected, a set of temporary anchoring system (a second set of temporary supporting system is assembled through prefabricated sections at the end parts of the cover girders of the hidden cover girders) needs to be arranged on the hidden cover girders so as to prevent the hidden cover girders from overturning due to unbalanced loads (such as the prefabricated small box girder assumed on one side, the self weight of a bridge girder erection machine and the like). The temporary anchoring system is dismantled before the prefabricated box girder splicing pouring after the prefabricated box girder is erected (namely, the bridge girder erection machine is not supported on the hidden cover girder), and if the temporary consolidation reaction frame does not influence the pouring of the wet joint and the dismantling of the reaction frame, the temporary anchoring system can be dismantled after the tensioning of the hogging moment beam of the prefabricated box girder is finished.

The temporary anchoring system is only suitable for hidden cover beam structures with cantilever ends, such as double-column type (two-side cantilever) and three-column type (single-side cantilever), and the temporary anchoring system can be omitted for four-column type hidden cover beams.

The temporary anchoring system adopts a 'anchor pressing type' structure, namely 1 channel of section steel beam is respectively arranged on the upper edge and the lower edge of the precast segment of the hidden cover beam, and pre-tensioning force is applied between the section steel beams by using finish rolling screw-thread steel so as to tightly press the 2 channels of section steel beams.

The core element of the temporary anchoring system is the lossless consolidation, namely the temporary consolidation is realized on the premise of not damaging the precast section concrete of the hidden cover beam.

The columns of the temporary anchoring system are usually arranged at the edge of the bearing platform, and the position penetrating through the bridge deck is usually positioned in the splicing area of the hidden cover beams, and if the temporary anchoring holes are arranged at the position, the permanent construction of the temporary anchoring holes is seriously influenced.

3) After the prefabricated small box girder is erected, the prefabricated small box girder is placed on a third temporary supporting system before seam UHPC pouring and prestress steel bundle tensioning are carried out, the third temporary supporting system is completed before the prefabricated small box girder is erected (simultaneously with a temporary anchoring system), and the prefabricated small box girder is dismantled after the moment-negative beam tensioning is completed.

During construction, firstly hoisting the hidden cover beam prefabricated sections on the first set of temporary support system, then taking the hidden cover beam prefabricated sections as a support structure for erecting the prefabricated small box beams, and then erecting the prefabricated small box beams.

For the construction of the prefabricated assembled concrete beam bridge structure system, as shown in fig. 11, the utility model provides a construction method comprising the following construction steps:

(1) building a temporary supporting system of the hidden cover beam on the basis of the lower supporting structure;

(2) hoisting the hidden cover beam prefabricated sections to the position above the hidden cover beam temporary supporting system according to the requirement; after the required hidden cover beam prefabricated sections are hoisted in place, tensioning the transverse bridge direction prestressed steel bundles to enable all the hidden cover beam prefabricated sections to be integrally assembled along the transverse bridge direction to form an assembled hidden cover beam;

(3) removing the temporary supporting system of the hidden capping beam; meanwhile, a temporary anchoring system is formed between the hidden cover beam and the lower supporting structure so as to improve the anti-overturning capacity of the assembled hidden cover beam;

(4) constructing a small box girder temporary supporting system on the basis of the assembled hidden cover girder;

(5) based on the principle of span-inside beam raising, erecting each prefabricated small box girder one by one from the upper part of the assembled hidden cover girder by adopting a bridge girder erection machine, so that convex shear resistant stirrups at the beam ends of the small box girders are staggered with convex shear resistant stirrups at the splicing seam notches of the prefabricated sections of the hidden cover girder;

(6) pouring abutted seam UHPC

Pouring UHPC concrete at the position of a splicing seam between the prefabricated small box girder and the prefabricated sections of the hidden cover girder to form a UHPC filling layer;

(7) prestressed steel beam for coupling connection between tension anchor sections

Entering the small box girder prefabricated at one side from a manhole of the small box girder conventional section at one side of the hidden cover girder prefabricated section, and anchoring one end of a prestressed steel strand for coupling connection among sections to a coupling prestressed anchoring area among sections of a solid section at the end part of the small box girder at the side; then, the steel beams enter the small box girder prefabricated on the other side from the manhole of the conventional section of the small box girder on the other side of the prefabricated section of the hidden cover beam, the other end of the prestressed steel beam for coupling connection among the sections is anchored to the coupling prestressed anchoring area among the sections of the solid section at the end part of the small box girder on the side, and the prestressed steel beam for coupling connection among the sections is tensioned;

(8) temporary supporting system for disassembling temporary anchoring system and small box girder

And (4) dismantling the temporary anchoring system and the small box girder temporary supporting system.

Claims (6)

1. A prefabricated invisible cover beam is used for building a fully prefabricated small box girder type invisible cover beam structure system and comprises a hidden cover beam body and is characterized in that the hidden cover beam body is formed by splicing a plurality of hidden cover beam prefabricated sections, two adjacent hidden cover beam prefabricated sections are spliced in a male-female tooth embedding mode, and meanwhile, all the hidden cover beam prefabricated sections are connected into a whole through a transverse bridge-direction prestressed steel beam which is tensioned and anchored;

the hidden cover beam prefabricated segment is arranged on two end faces in the bridge direction, at least one end face is provided with a small box beam splicing seam notch capable of being embedded with the end part of a prefabricated small box beam, and a plurality of rows of splicing seam notch convex shear-resistant stirrups are distributed in the small box beam splicing seam notch along the vertical direction.

2. The prefabricated invisible capping beam as claimed in claim 1, wherein the hidden capping beam prefabricated section comprises a hidden capping beam middle pivot section, and can be spliced to form a hidden capping beam body arranged in a middle pivot area;

the hidden bent cap middle fulcrum section comprises a middle fulcrum bent cap middle section body and a middle fulcrum bent cap end section body;

the two end surfaces in the bridge direction of the middle section body of the middle fulcrum bent cap/the end section body of the middle fulcrum bent cap are both provided with bent cap joint surfaces which are correspondingly a first bent cap joint surface and a second bent cap joint surface; the middle section body of the middle fulcrum bent cap/the end section body of the middle fulcrum bent cap are provided with prestressing ducts along the bridge direction through the first bent cap joint surface and the second bent cap joint surface;

the two end surfaces of the middle section body of the middle fulcrum bent cap in the transverse bridge direction are respectively provided with a bent cap section splicing surface, and correspondingly comprise a first bent cap section splicing surface and a second bent cap section splicing surface; the middle section body of the middle fulcrum bent cap penetrates through the splicing surface of the first bent cap section and the splicing surface of the second bent cap section to form a transverse bridge-direction prestressed steel beam pore channel;

the end face of the middle fulcrum bent cap end section body, which is positioned in two end faces in the transverse bridge direction, only positioned on the inner side is provided with a bent cap section splicing face;

the capping beam joint surface is provided with a small box girder joint notch penetrating through the top surface of the corresponding hidden capping beam prefabricated section;

the splicing surface of the first bent cap section is arranged away from the middle point of the spliced hidden bent cap, and a plurality of concave tooth blocks are arranged on the splicing surface of the first bent cap section;

the splicing surface of the second bent cap section is arranged close to the middle point of the spliced hidden bent cap, and the splicing surface of the second bent cap section is provided with an outer convex tooth block; the positions of the concave tooth blocks on the two sides of the middle section body of each middle fulcrum bent cap correspond to the positions of the convex tooth blocks;

the transverse bridge-direction prestressed steel beam pore ways are arranged in a staggered manner with the outer convex tooth blocks/the inner concave tooth blocks;

transverse bridge-direction prestress steel beams are pre-buried in the end section bodies of the middle fulcrum bent caps, the end section bodies of the middle fulcrum bent caps are positioned on the splicing surfaces of the bent caps in the transverse bridge direction, and convex tooth blocks matched with the concave tooth blocks corresponding to the middle section bodies of the middle fulcrum bent caps are arranged; each transverse bridge-direction prestressed steel beam pore passage corresponds to a transverse bridge-direction prestressed steel beam pre-embedded in the middle fulcrum bent cap end section body.

3. The prefabricated invisible capping beam as claimed in claim 2, wherein the splice-notch convex shear stirrups are distributed in three rows in the splice notch of the small box girder, corresponding to the middle-row splice-notch convex shear stirrups and the side splice-notch convex shear stirrups symmetrically arranged at both sides of the middle-row splice-notch convex shear stirrups; the convex shear-resistant stirrups of all rows of abutted seam notches are arranged along the height direction of the abutted seam notches of the small box girders.

4. The precast assembled invisible capping beam of claim 3, wherein the abutted notch convex shear resistant stirrups are U-shaped reinforcing steel bars; the two ends of the U-shaped reinforcing steel bar are embedded in the groove bottom of the small box girder splicing groove opening, and the closed section of the U-shaped reinforcing steel bar protrudes outwards from the groove bottom of the small box girder splicing groove opening.

5. The prefabricated invisible capping beam as claimed in claim 2, wherein the hidden capping beam prefabricated section comprises a hidden capping beam middle pivot section, and can be spliced to form a hidden capping beam body arranged in a middle pivot area;

the hidden bent cap edge fulcrum section comprises an edge fulcrum bent cap middle section body and an edge fulcrum bent cap end section body;

the structure of the middle section body of the side fulcrum bent cap in the transverse bridge direction is consistent with the structure of the middle section body of the middle fulcrum bent cap in the transverse bridge direction;

the structure of the end section body of the side fulcrum bent cap in the transverse bridge direction is consistent with the structure of the end section body of the middle fulcrum bent cap in the transverse bridge direction;

the hidden cover beam edge fulcrum section is positioned in two end faces along the bridge direction, and the end face close to the middle fulcrum area is provided with a cover beam joint surface.

6. The prefabricated invisible capping beam as claimed in claim 2, wherein the concave teeth blocks are distributed in 3 rows on the splicing surface of the first capping beam segment, corresponding to the first, second and third rows of concave teeth blocks, each of the first, second and third rows of concave teeth blocks comprises a plurality of concave teeth blocks distributed along the height direction of the splicing surface of the first capping beam segment, the first row of concave teeth blocks is located in the middle direction of the splicing surface of the first capping beam segment, and the second and third rows of concave teeth blocks are symmetrically distributed on two sides of the first row of concave teeth blocks;

the convex tooth blocks are distributed into 3 rows on the splicing surface of the second cover beam section and are correspondingly provided with a first row of convex tooth blocks, a second row of convex tooth blocks and a third row of convex tooth blocks, the first row of convex tooth blocks, the second row of convex tooth blocks and the third row of convex tooth blocks respectively comprise a plurality of convex tooth blocks distributed along the height direction of the splicing surface of the first cover beam section, the first row of convex tooth blocks are positioned in the middle direction of the splicing surface of the first cover beam section, and the second row of convex tooth blocks and the third row of convex tooth blocks are symmetrically distributed on two sides of the first row of convex tooth blocks;

in each hidden cover beam middle section, the positions of all the inner concave tooth blocks in the first row of inner concave tooth blocks correspond to the positions of all the outer convex tooth blocks in the first row of outer convex tooth blocks, the positions of all the inner concave tooth blocks in the second row of inner concave tooth blocks correspond to the positions of all the outer convex tooth blocks in the second row of outer convex tooth blocks, and the positions of all the inner concave tooth blocks in the third row of inner concave tooth blocks correspond to the positions of all the outer convex tooth blocks in the third row of outer convex tooth blocks.

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