Antibacterial and mildew-proof combined type anti-drop floor

Abstract

The utility model discloses an antibacterial mildewproof combined type drop-resistant floor, the floor bottom is equipped with the bottom plate with antiskid line, and the top is the composite board, and the middle array distribution support block enhances drop-resistant performance, and the bottom plate inside has the locating groove, and the built -in buffer ring is connected with the support block nest, promotes the stability and the buffer effect, and the top plate of composite board top is equipped with the bacteriostatic layer, and the bacteria and mould breeding is inhibited, and the antiskid boss on the top plate surface increases the antiskid property, in addition, the embedded groove of floor outside and the nested part staggered arrangement, convenient splicing installation, this kind of floor integrates antibacterial mildewproof, drop -resistant, antiskid etc.

Description

Technical Field

[0001] This utility model belongs to the technical field of building decoration, specifically relating to an antibacterial and mildew-proof combination anti-fall floor. Background Technology

[0002] Flooring is a material used to cover the interior ground or floor of a building. In addition to its basic decorative function of beautifying the interior space and creating different styles and atmospheres, flooring also has a certain load-bearing capacity, which can withstand the pressure generated by daily foot traffic and furniture placement. It is also a building decoration material with a wide variety of material types and diverse characteristics.

[0003] However, existing ordinary flooring does not have good drop resistance and is easily broken and damaged when subjected to large impacts, which increases the cost of use and maintenance difficulty. At the same time, in some humid environments, the flooring is prone to the growth of bacteria and mold, which not only affects the appearance but also poses a threat to human health. Utility Model Content

[0004] The purpose of this utility model is to provide an antibacterial and mildew-resistant combination anti-fall floor to solve the problems mentioned in the background art, such as the lack of good anti-fall performance of existing ordinary floors, their easy breakage and damage when subjected to large impacts, which increases the cost of use and maintenance difficulty. At the same time, in some humid environments, the floor is prone to the growth of bacteria and mold, which not only affects the appearance but also poses a threat to human health.

[0005] To achieve the above objectives, this utility model provides the following technical solution: an antibacterial and mildew-resistant combined anti-fall floor, comprising an anti-fall floor body;

[0006] The bottom of the anti-fall floor is provided with a base plate, and the bottom of the base plate is provided with anti-slip texture;

[0007] A composite board is provided at the top of the main body of the anti-fall floor, and support blocks are arranged in an array between the bottom plate and the composite board.

[0008] Preferably, the base plate has a positioning groove arrayed inside, and an insert is provided inside the positioning groove. The positioning groove and the insert are nested and connected with the support block.

[0009] Preferably, a buffer ring is provided inside the positioning groove, and the buffer ring is made of TPE environmentally friendly material.

[0010] Preferably, the composite board is provided with a top plate at the top position, an antibacterial layer is provided at the bottom position of the top plate, and anti-slip protrusions are provided at the top position of the top plate.

[0011] Preferably, a lower plate is provided at the bottom of the antibacterial layer, and an array of plug-in blocks are arranged at the bottom of the lower plate, the plug-in blocks being plugged into and connected to the support block.

[0012] Preferably, the outer side of the anti-fall floor body is provided with nesting members, and the outer side of the anti-fall floor body is provided with grooves. The grooves and nesting members are arranged alternately, and the anti-fall floor body is spliced ​​together by the grooves and nesting members.

[0013] Compared with the prior art, this utility model provides an antibacterial and mildew-proof combination anti-fall floor, which has the following beneficial effects:

[0014] The anti-fall flooring is structured with composite panels, support blocks, positioning grooves, inserts, buffer rings, a top plate, an antibacterial layer, a bottom plate, and interlocking blocks. The top of the main body is a composite panel, with support blocks arranged in an array between the bottom plate and the composite panel. These support blocks cushion the impact of external forces, dispersing the force and preventing breakage due to excessive localized stress. This significantly enhances the floor's anti-fall performance and effectively extends its lifespan. Positioning grooves are arrayed inside the bottom plate, with inserts nested within them. These grooves and inserts are nested with the support blocks, ensuring precise and stable installation and guaranteeing accurate support. This improves the overall stability of the flooring structure. Buffer rings made of synthetic rubber are located inside the positioning grooves. The rubber material's elasticity and flexibility allow the buffer rings to further absorb and cushion impacts, reducing the force transmitted to other parts of the flooring. The flooring's impact resistance and slip resistance are enhanced. An antibacterial layer is installed at the bottom of the top panel of the composite board, effectively inhibiting the growth and reproduction of bacteria and mold, keeping the floor surface clean and hygienic. This is particularly suitable for places with high hygiene requirements, such as hospitals and food processing workshops, reducing health risks caused by bacterial and mold growth. Anti-slip protrusions are installed at the top of the top panel, increasing friction between the floor surface and shoe soles or other contact objects, thereby improving the floor's anti-slip performance, reducing the possibility of slips and injuries, and ensuring safety during use. The interlocking connection between the top panel, antibacterial layer, and support blocks is achieved by an array of interlocking blocks at the bottom of the bottom panel of the antibacterial layer, which interlock with the support blocks. This connection method not only makes the connection between the top panel, antibacterial layer, and other components and the support blocks tighter, but also further enhances the overall integrity and stability of the floor structure, ensuring that all components work together to achieve optimal performance. Attached Figure Description

[0015] Figure 1 This is a schematic diagram of the structure of this utility model.

[0016] Figure 2 This is a schematic diagram of the structure of the base plate of this utility model.

[0017] Figure 3 This is a schematic diagram of the composite plate in this utility model.

[0018] Figure 4 This is a structural schematic diagram of the cross-section of the main body of the anti-fall floor in this utility model.

[0019] Figure 5 This is a schematic diagram of the bottom structure of the base plate in this utility model.

[0020] Figure 6 This is a schematic diagram of the structure of the floor body in this utility model.

[0021] In the diagram: 1. Main body of the anti-fall floor; 2. Base plate; 3. Positioning groove; 4. Inlay; 5. Composite board; 6. Bottom plate; 7. Anti-slip texture; 8. Buffer ring; 9. Support block; 10. Insert block; 11. Antibacterial layer; 12. Top plate; 13. Anti-slip protrusion; 14. Nesting piece; 15. Inlay groove. Detailed Implementation

[0022] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0023] This utility model provides, for example Figure 1-6 The antibacterial and mildew-resistant combination anti-fall floor shown includes an anti-fall floor body 1;

[0024] The bottom of the anti-fall floor body 1 is provided with a base plate 2, and the bottom of the base plate 2 is provided with anti-slip texture 7;

[0025] A composite board 5 is installed at the top of the main body 1 of the anti-fall floor, and support blocks 9 are arranged in an array between the bottom plate 2 and the composite board 5.

[0026] The base plate 2 has a positioning groove 3 arrayed inside, and an insert 4 is provided inside the positioning groove 3. The positioning groove 3 and the insert 4 are nested and connected with the support block 9.

[0027] A buffer ring 8 is provided inside the positioning groove 3. The buffer ring 8 is made of TPE environmentally friendly material.

[0028] A top plate 12 is provided at the top of the composite board 5, an antibacterial layer 11 is provided at the bottom of the top plate 12, and anti-slip protrusions 13 are provided at the top of the top plate 12.

[0029] A lower plate 6 is provided at the bottom of the antibacterial layer 11, and an array of plug-in blocks 10 are arranged at the bottom of the lower plate 6. The plug-in blocks 10 are plugged into and connected to the support block 9.

[0030] The outer side of the anti-fall floor body 1 is provided with nesting parts 14, and the outer side of the anti-fall floor body 1 is provided with grooves 15. The grooves 15 and the nesting parts 14 are arranged alternately, and the anti-fall floor body 1 is spliced ​​together by the grooves 15 and the nesting parts 14.

[0031] In this embodiment, the specific implementation steps of an antibacterial and mildew-resistant composite anti-fall floor are as follows: The base plate 2 with anti-slip texture 7 is placed on a cleaned surface. Due to the anti-slip texture 7 on the bottom of the base plate 2, it provides a certain amount of friction during installation, preventing the base plate from sliding. The inserts 4 at the bottom of the support blocks 9 are aligned with the positioning grooves 3 arrayed inside the base plate 2 for nesting connection. Each support block 9 must be accurately installed in its corresponding positioning groove 3 to ensure a secure installation. The buffer ring 8 inside the positioning groove 3, made of TPE environmentally friendly material, surrounds the bottom of the support block 9, providing a cushioning effect and enhancing the overall anti-fall performance of the floor. The composite board 5 is then placed on the installed support blocks. Above 9, align the composite board 5 with the support block 9 to ensure that the composite board 5 is placed stably on the support block 9. Then install the top plate 12 and its related components. The bottom of the top plate 12 is provided with an antibacterial layer 11. Place them together on top of the composite board 5. At this time, the plug-in blocks 10 arranged in the bottom array of the bottom plate 6 of the antibacterial layer 11 are plugged into the support block 9 to further stabilize the entire floor structure. According to the size and shape requirements of the installation site, the floor is spliced ​​by the interlocking grooves 15 and nesting pieces 14 arranged on the outside of the anti-fall floor body 1. Insert the nesting piece 14 of one floor into the corresponding groove 15 of another floor, and complete the splicing work of the entire site in sequence.

[0032] like Figure 1-4 As shown, a composite board 5 is installed at the top of the anti-fall floor body 1. Support blocks 9 are arranged in an array between the bottom plate 2 and the composite board 5. Positioning grooves 3 are arranged in an array inside the bottom plate 2. An insert 4 is arranged inside the positioning groove 3. The positioning groove 3 and the insert 4 are nested and connected with the support blocks 9. A buffer ring 8 is arranged inside the positioning groove 3. The buffer ring 8 is made of TPE environmentally friendly material. A top plate 12 is installed at the top of the composite board 5. An antibacterial layer 11 is installed at the bottom of the top plate 12. Anti-slip protrusions 13 are installed at the top of the top plate 12. A bottom plate 6 is installed at the bottom of the antibacterial layer 11. Insertion blocks 10 are arranged in an array at the bottom of the bottom plate 6. The insertion blocks 10 are inserted and connected with the support blocks 9.

[0033] Preferably, the top of the anti-fall floor body 1 is provided with a composite board 5, and support blocks 9 are arranged in an array between the bottom plate 2 and the composite board 5. The support blocks 9 can provide support and cushioning when the floor is impacted by external forces, disperse the impact force, and prevent the floor from cracking due to excessive local stress, greatly enhancing the anti-fall performance of the floor and effectively extending the service life of the floor. The bottom plate 2 has positioning grooves 3 arranged in an array inside, and the positioning grooves 3 and the inserts 4 are set inside the positioning grooves 3. The positioning grooves 3 and the inserts 4 are nested and connected with the support blocks 9. This connection method makes the support blocks 9 more precise and stable during installation, ensuring that the support blocks 9 can accurately play their supporting role and improving the stability of the entire floor structure. The positioning grooves 3 are provided with buffer rings 8 made of TPE environmentally friendly material. TPE environmentally friendly material has good elasticity and flexibility. When the floor is impacted, the buffer rings 8 can further absorb and cushion the impact force, reduce the force transmitted to other parts of the floor, enhance the impact resistance of the floor, and improve the anti-fall effect. An antibacterial layer 11 is provided at the bottom of the top plate 12 of the composite board 5. The antibacterial layer 11 can effectively inhibit the growth and reproduction of bacteria and mold, keeping the floor surface clean and hygienic. It is especially suitable for places with high hygiene requirements, such as hospitals and food processing workshops, and can reduce the health risks caused by the growth of bacteria and mold. Anti-slip protrusions 13 are provided at the top of the top plate 12, which increases the friction between the floor surface and the soles of shoes or other contact objects, thereby improving the anti-slip performance of the floor, reducing the possibility of people slipping and getting injured, and ensuring safety during use. The plug-in block 10 is connected to the support block 9 by an array of plug-in blocks 10 at the bottom of the bottom plate 6 of the bottom of the antibacterial layer 11. The plug-in block 10 is connected to the support block 9 by plugging in. This connection method not only makes the connection between the top plate 12, antibacterial layer 11 and other components and the support block 9 tighter, but also further enhances the integrity and stability of the entire floor structure, ensuring that all components work together to achieve the best performance.

[0034] like Figure 1-6 As shown, nesting pieces 14 are arranged in an array on the outer side of the anti-fall floor body 1, and grooves 15 are arranged in an array on the outer side of the anti-fall floor body 1. The grooves 15 and the nesting pieces 14 are arranged alternately, and the anti-fall floor body 1 is spliced ​​together by the grooves 15 and the nesting pieces 14.

[0035] Optionally, the grooves 15 and the nesting pieces 14 are staggered, making the splicing process of the anti-fall floor body 1 simple and direct. At the installation site, the construction workers only need to align the nesting piece 14 of one floor with the groove 15 of another floor and then perform a simple embedding operation to complete the connection between adjacent floorboards. Compared with some complex splicing methods, this design greatly saves installation time and labor costs and improves installation efficiency. Each anti-fall floor body 1 can be tightly combined to form a continuous and unified whole structure. This integrity helps to disperse the pressure and impact force borne by the floor, enabling the entire floor system to better cope with various external forces and further improve the anti-fall performance and durability of the floor. Due to the standardized design of the grooves 15 and the nesting pieces 14, the splicing layout of the floor can be flexibly adjusted according to the shape, size and usage requirements of the actual site during the laying process.

[0036] Finally, it should be noted that the above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Although the present utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.

Claims

1. An antibacterial and mildew-resistant combination anti-fall floor, comprising an anti-fall floor body (1); The bottom of the anti-fall floor body (1) is provided with a bottom plate (2), and the bottom of the bottom plate (2) is provided with anti-slip texture (7); Its features are: A composite board (5) is provided at the top of the main body (1) of the anti-fall floor, and a support block (9) is arranged in an array between the bottom plate (2) and the composite board (5).

2. The antibacterial and mildew-resistant combined anti-fall flooring according to claim 1, characterized in that: The base plate (2) has a positioning groove (3) arranged in an array at the inside position, and an insert (4) is provided at the inside position of the positioning groove (3). The positioning groove (3) and the insert (4) are nested and connected with the support block (9).

3. The antibacterial and mildew-resistant combined anti-fall flooring according to claim 2, characterized in that: A buffer ring (8) is provided inside the positioning groove (3), and the buffer ring (8) is made of TPE environmentally friendly material.

4. The antibacterial and mildew-resistant combined anti-fall flooring according to claim 3, characterized in that: The composite board (5) is provided with a top plate (12) at the top position, an antibacterial layer (11) is provided at the bottom position of the top plate (12), and an anti-slip protrusion (13) is provided at the top position of the top plate (12).

5. The antibacterial and mildew-resistant combined anti-fall flooring according to claim 4, characterized in that: A lower plate (6) is provided at the bottom of the antibacterial layer (11), and a plug-in block (10) is arranged in an array at the bottom of the lower plate (6). The plug-in block (10) is plugged into and connected to the support block (9).

6. The antibacterial and mildew-resistant combined anti-fall flooring according to claim 1, characterized in that: The outer side of the anti-fall floor body (1) is provided with nesting parts (14), and the outer side of the anti-fall floor body (1) is provided with grooves (15). The grooves (15) and the nesting parts (14) are arranged alternately, and the anti-fall floor body (1) is spliced ​​together by the grooves (15) and the nesting parts (14).

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