A floor slab reinforcement structure

By combining support components and support beams, along with worm gear transmission and a high-strength reinforcement layer, the problem of inconsistent spacing at floor slab joints was solved, resulting in improved stability and reinforcement.

CN224431769UActive Publication Date: 2026-06-30GUANGDONG YAONAN CONSTR ENG CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
GUANGDONG YAONAN CONSTR ENG CO LTD
Filing Date
2024-11-08
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

When the joint spacing of existing reinforced concrete floor slabs is inconsistent, the support positioning protrusions cannot provide effective support, resulting in poor reinforcement effect.

Method used

The system employs a combination structure of support components and support beams. The support components include a support base and a connecting protrusion. The position of the connecting protrusion is adjusted via a worm gear transmission. The system is reinforced with a high-strength reinforcement layer. The support base is equipped with a worm gear transmission system and a positioning slot and positioning block for precise positioning.

Benefits of technology

It achieves stable support and reinforcement of floor slabs under different spacing conditions, improves the stability and reinforcement effect of floor slabs, and enhances the overall rigidity and durability of floor slabs by using high-strength materials.

✦ Generated by Eureka AI based on patent content.

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Abstract

This application discloses a floor slab reinforcement structure, relating to the field of floor slab reinforcement technology. It includes two floor slab bodies, a support beam connecting the two floor slab bodies, and two support components supporting the floor slab bodies and the support beam. Each support component includes a support column, with a support seat fixedly connected to the top outer wall of the support column. The top outer wall of the support seat has four symmetrically arranged openings, and the inner walls of each of the four openings are slidably connected to two connecting protrusions. The bottom outer wall of the floor slab body has connecting grooves that match the connecting protrusions. This application, by setting support beams and support components on the floor slab bodies, and the cooperation between the support components and the support beams, facilitates the reinforcement and support of the floor slab bodies, improving the stability of the floor slab. Furthermore, by setting a reinforcement layer on the floor slab bodies, made of high-strength and high-durability materials, the stability of the floor slab is further improved.
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Description

Technical Field

[0001] This application relates to the field of floor slab reinforcement technology, and in particular to a floor slab reinforcement structure. Background Technology

[0002] Concrete floor slabs have high strength, good rigidity, good fire resistance and durability, and good plasticity. They are easy to industrialize and widely used in my country. According to different construction methods, they can be divided into three types: cast-in-place, prefabricated, and prefabricated monolithic. Reinforced concrete structures refer to structures made of concrete reinforced with steel bars. The main load-bearing components are constructed of reinforced concrete.

[0003] A search revealed a Chinese patent publication number CN112983040A, which discloses a reinforced concrete floor slab structure, including a first floor slab, a second floor slab, a beam, and a column. A steel column is fixedly installed inside the first floor slab, a transverse steel plate is fixedly installed at the bottom of the steel column, and a transverse column is fixedly installed at the bottom of the transverse steel plate. A perforation is formed inside the first floor slab, and a top column is fixedly installed on the top of the transverse steel plate, extending through the perforation and reaching the top of the perforation. A connecting ring is fixedly installed on the outer side of the top column.

[0004] The above-mentioned concrete floor slab reinforcement structure has the following shortcomings: The above-mentioned patent uses the setting of columns to assist in the reinforcement of the floor slab, but in actual operation, the splice joints between the floor slabs sometimes have different spacings in order to match the actual size, while the spacing between the positioning protrusions on the columns is fixed, which means that the columns cannot effectively support and reinforce the floor slab. Utility Model Content

[0005] In order to improve the problem that existing floor slab reinforcement structures are inconvenient to effectively support the floor slab, this application provides a floor slab reinforcement structure.

[0006] This application provides a floor slab reinforcement structure, including two floor slab bodies, a support beam connecting the two floor slab bodies, and two support components supporting the floor slab bodies and the support beam. The support components include support columns, and a support seat is fixedly connected to the top outer wall of the support column. The top outer wall of the support seat has four symmetrically arranged openings, and the inner walls of the four openings are slidably connected to two connecting protrusions. The bottom outer wall of the floor slab body has a connecting groove that matches the connecting protrusions.

[0007] Using the above structure, the floor slab body is supported by the cooperation between the support components and the support beams. The connecting protrusions on the support base can be adjusted to match the spacing between different floor slab bodies, thereby facilitating the reinforcement of the floor slab.

[0008] The inner wall of the support base has an installation cavity, and an installation rod is fixedly connected to the inner wall of the installation cavity.

[0009] The above structure facilitates the installation of the mounting rod through the installation cavity.

[0010] The outer wall of the mounting rod is slidably connected to two sliding seats, and the two sliding seats are respectively fixedly connected to two connecting protrusions.

[0011] With the above structure, the movement trajectory of the sliding seat can be easily restricted by the mounting rod.

[0012] A worm gear is rotatably connected to the inner wall at the bottom of the mounting cavity, and a rotating disk is fixedly connected to one end of the worm gear drive shaft.

[0013] With the above structure, the worm gear facilitates the rotation of the rotating disk.

[0014] The top outer wall of the rotating disk is eccentrically connected to two connecting plates, which are respectively rotatably connected to two sliding seats. The inner walls on both sides of the mounting cavity are rotatably connected to worm gears that mesh with the worm wheel.

[0015] With the above structure, the worm gear drives the worm wheel to rotate, which in turn drives the rotating disk to move the connecting plate.

[0016] The outer wall of one side of the support base is provided with a circular groove, and the inner wall of the circular groove is rotatably connected to a rotating part that is connected to a drive shaft and a worm gear.

[0017] With the above structure, the rotating part allows for easy and direct rotation of the worm gear.

[0018] The top outer wall of the support base is provided with a positioning groove, and the specifications of the positioning groove match the specifications of the positioning block.

[0019] The above structure facilitates the positioning of the support beam through the cooperation between the positioning block and the positioning groove.

[0020] The floor slab body includes a floor slab layer, and a connecting layer is provided on the bottom outer wall of the floor slab layer, and a reinforcing layer is provided on the bottom outer wall of the connecting layer.

[0021] The above structure uses high-strength, high-durability steel plates for the reinforcement layer, which facilitates the reinforcement of the floor slab. The connection layer uses special adhesives or welding methods to tightly connect the reinforcement layer to the floor slab.

[0022] In summary, the beneficial effects of this application are as follows:

[0023] 1. This application improves the stability of the floor slab by setting support beams and support components on the floor slab body and cooperating with the support components and support beams to strengthen and support the floor slab body. Furthermore, a reinforcement layer is set on the floor slab body, which is made of high-strength and high-durability materials, further improving the stability of the floor slab.

[0024] 2. This application provides two adjustable sliding seats in the support base. Adjusting the sliding seats makes it easy to adjust the position of the two connecting protrusions, which in turn facilitates the matching of different specifications of gaps between floor slabs. Furthermore, a reinforcing layer is provided on the floor slab body to facilitate the reinforcement of the floor slab body. Attached Figure Description

[0025] Figure 1 This is an overall schematic diagram of this application;

[0026] Figure 2 This is a schematic diagram of the supporting beam in this application;

[0027] Figure 3 This is a schematic diagram of the supporting components of this application;

[0028] Figure 4 This is a cross-sectional view of the support base of this application;

[0029] Figure 5 This is a schematic diagram of the floor slab structure in this application.

[0030] Explanation of reference numerals in the attached drawings: 1. Floor slab body; 2. Support beam; 3. Support assembly; 4. Positioning block; 5. Support column; 6. Support seat; 7. Connecting protrusion; 8. Opening; 9. Positioning groove; 10. Rotating part; 11. Mounting cavity; 12. Worm gear; 13. Worm wheel; 14. Rotating disk; 15. Connecting plate; 16. Mounting rod; 18. Sliding seat; 19. Floor slab layer; 20. Connecting layer; 21. Reinforcing layer. Detailed Implementation

[0031] The following is in conjunction with the appendix Figure 1-5 This application will be described in further detail.

[0032] Please see Figure 1-3A floor slab reinforcement structure includes two floor slab bodies 1, a support beam 2 connecting the two floor slab bodies 1, and two support components 3 supporting the floor slab bodies 1 and the support beam 2. The floor slab bodies 1 are supported by the cooperation between the support components 3 and the support beam 2. The support components 3 include support columns 5, and support seats 6 are fixedly connected to the top outer wall of the support columns 5. The top outer wall of the support seats 6 has four symmetrically arranged openings 8, and the inner walls of the four openings 8 are slidably connected to two connecting protrusions 7. The bottom outer wall of the floor slab bodies 1 has connecting grooves that match the connecting protrusions 7. The connecting protrusions 7 on the support seats 6 can be adjusted according to the spacing between different floor slab bodies 1, thereby facilitating the reinforcement of the floor slab.

[0033] Reference Figure 4 The inner wall of the support base 6 is provided with an installation cavity 11, and an installation rod 16 is fixedly connected to the inner wall of the installation cavity 11. The installation cavity 11 facilitates the installation of the installation rod 16.

[0034] Reference Figure 4 The outer wall of the mounting rod 16 is slidably connected to two sliding seats 18, and the two sliding seats 18 are respectively fixedly connected to two connecting protrusions 7. The mounting rod 16 can conveniently restrict the movement trajectory of the sliding seats 18.

[0035] Reference Figure 4 A worm gear 13 is rotatably connected to the inner wall of the bottom of the mounting cavity 11, and a rotating disk 14 is fixedly connected to one end of the drive shaft of the worm gear 13. The worm gear 13 facilitates the rotation of the rotating disk 14.

[0036] Reference Figure 4 Two connecting plates 15 are eccentrically rotatably connected to the top outer wall of the rotating disk 14, and the two connecting plates 15 are rotatably connected to two sliding seats 18 respectively. The inner walls on both sides of the mounting cavity 11 are rotatably connected to worm gears 12 that mesh with worm wheels 13. The worm gears 12 drive the worm wheels 13 to rotate, thereby driving the rotating disk 14 to move the connecting plates 15.

[0037] Reference Figure 3 A circular groove is provided on one outer wall of the support base 6, and a rotating part 10 connected to the drive shaft and the worm gear 12 is rotatably connected to the inner wall of the circular groove. The rotating part 10 facilitates the direct rotation of the worm gear 12.

[0038] Reference Figure 3-4 The top outer wall of the support base 6 is provided with a positioning groove 9, and the specifications of the positioning groove 9 match the specifications of the positioning block 4. The positioning block 4 and the positioning groove 9 cooperate to facilitate the positioning of the support beam 2.

[0039] Reference Figure 5The floor slab body 1 includes a floor slab layer 19, and a connecting layer 20 is provided on the bottom outer wall of the floor slab layer 19. A reinforcing layer 21 is provided on the bottom outer wall of the connecting layer 20. The reinforcing layer 21 is made of high-strength and high-durability steel plate material, which facilitates the reinforcement of the floor slab body 1. The connecting layer 20 is tightly connected to the floor slab layer 19 by special adhesive or welding.

[0040] The implementation principle of this application is as follows: In use, the cooperation between the support component 3 and the support beam 2 facilitates the support of the two floor slab bodies 1. The rotation of the rotating part 10 in the support seat 6 drives the worm gear 12 to rotate, which in turn drives the worm wheel 13 to rotate, directly driving the rotating disk 14 to rotate. When the rotating disk 14 rotates, it directly pulls the sliding seat 18 to move through the connecting plate 15, thereby adjusting the position of the connecting protrusion 7. The connecting protrusion 7 is adjusted according to the distance between the two floor slab bodies 1, thereby facilitating stable support of the floor slab bodies 1.

[0041] The above are all preferred embodiments of this application, and are not intended to limit the scope of protection of this application. Therefore, all equivalent changes made in accordance with the structure, shape and principle of this application should be covered within the scope of protection of this application.

Claims

1. A floor slab reinforcement structure, comprising two floor slab bodies (1), a support beam (2) connecting the two floor slab bodies (1), and two support components (3) supporting the floor slab bodies (1) and the support beam (2), characterized in that: The support component (3) includes a support column (5), and a support seat (6) is fixedly connected to the top outer wall of the support column (5). The top outer wall of the support seat (6) has four symmetrically arranged openings (8), and the inner walls of the four openings (8) are slidably connected to two connecting protrusions (7). The bottom outer wall of the floor slab body (1) has a connecting groove that matches the connecting protrusions (7). The inner wall of the support base (6) is provided with an installation cavity (11), and an installation rod (16) is fixedly connected to the inner wall of the installation cavity (11). The outer wall of the mounting rod (16) is slidably connected to two sliding seats (18), and the two sliding seats (18) are respectively fixedly connected to two connecting protrusions (7); The bottom inner wall of the mounting cavity (11) is rotatably connected to a worm gear (13), and one end of the drive shaft of the worm gear (13) is fixedly connected to a rotating disk (14). The top outer wall of the rotating disk (14) is eccentrically connected to two connecting plates (15), and the two connecting plates (15) are rotatably connected to two sliding seats (18) respectively. The inner walls on both sides of the mounting cavity (11) are rotatably connected to worms (12) that mesh with the worm wheel (13). The outer wall of one side of the support base (6) is provided with a circular groove, and the inner wall of the circular groove is rotatably connected to a rotating part (10) that is connected to a drive shaft and a worm gear (12).

2. The floor slab reinforcement structure according to claim 1, characterized in that: The support base (6) has a positioning groove (9) on its top outer wall, and the specifications of the positioning groove (9) match the specifications of the positioning block (4).

3. The floor slab reinforcement structure according to claim 2, characterized in that: The floor slab body (1) includes a floor slab layer (19), and a connecting layer (20) is provided on the bottom outer wall of the floor slab layer (19), and a reinforcing layer (21) is provided on the bottom outer wall of the connecting layer (20).