Porous habitat ecological revetment block capable of purifying rainwater
The design of the revetment blocks with snap-fit connections and built-in sponge-filled drainage holes solves the problem of rainwater corrosion, achieves the stability of the revetment blocks and rainwater purification, and extends their service life.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HUBEI SHUNAN WATER CONSERVANCY & HYDROPOWER INSTALLATION ENG CO LTD
- Filing Date
- 2025-07-22
- Publication Date
- 2026-06-09
AI Technical Summary
During rainy weather, impurities in the existing revetment blocks flow directly into their interiors, causing corrosion and reducing their lifespan.
A porous, habitable ecological revetment block capable of purifying rainwater is designed. The revetment blocks are connected by slots and blocks, and barrier strips and drainage holes are installed. The drainage holes are filled with sponge material to absorb impurities, thereby purifying rainwater.
It improves the structural stability and rainwater purification effect of the revetment blocks, extends the service life of the revetment blocks, prevents corrosion, and maintains construction efficiency and the integrity of the overall structure.
Smart Images

Figure CN224338173U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of revetment block technology, specifically a porous, habitable ecological revetment block that can purify rainwater. Background Technology
[0002] Revetment blocks are structures used to protect riverbanks, coastlines, and other waterside areas. They are typically made of materials such as concrete and stone. Revetment blocks come in various shapes, including cubes and tetrahedrons. Their main function is to resist erosion from water flow and waves, preventing bank collapse. The blocks are arranged closely together to increase overall stability. They are widely used in hydraulic engineering and marine engineering. By using revetment blocks, it is possible to effectively protect coastal infrastructure, the ecological environment, and human settlements, reducing safety risks and economic losses caused by bank erosion.
[0003] The existing revetment blocks can only prevent erosion of the waterfront. When it rains, impurities in the rainwater fall into the interior of the revetment blocks. Because the impurities in the rainwater flow directly into the interior of the revetment blocks, they directly cause corrosion at the bottom and reduce the lifespan of the revetment blocks. Utility Model Content
[0004] To solve the above-mentioned technical problems, this utility model provides a porous habitat ecological revetment block that can purify rainwater, including a revetment block one, a slot is provided on the top of the revetment block one, a locking block is engaged inside the slot, and a revetment block two is fixedly connected to the surface of the locking block.
[0005] The top of the revetment block 1 is provided with a drainage hole, and the top of the revetment block 1 is provided with a limiting groove. The bottom of the inner wall of the limiting groove is provided with a locking hole. A locking post is locked inside the locking hole. A barrier strip is fixedly connected to the top of the locking post. A limiting block is fixedly connected to the bottom of the barrier strip. A connecting strip is fixedly connected to the surface of the limiting block. A filling block is provided at the bottom of the connecting strip.
[0006] Through the above technical solution, revetment block one and revetment block two are connected by a slot and a snap-fit method. This connection method makes the assembly of revetment blocks more convenient, facilitates splicing operations when constructing revetment, helps improve construction efficiency, and also makes it easier to adjust the shape and scale of revetment according to actual needs. The barrier strip can block rainwater and allow it to flow out through the drainage hole.
[0007] As a further improvement to the above scheme, the diameter of the first revetment block and the second revetment block are the same.
[0008] With the above technical solution, the revetment block one and revetment block two have the same diameter, which helps to ensure the integrity and stability of the revetment structure after splicing, makes the revetment surface smoother, reduces structural weak points that may be caused by size differences, improves the overall structural strength of the revetment, and better resists the impact of external forces such as water flow.
[0009] As a further improvement to the above scheme, two limiting grooves are provided. The two limiting grooves are symmetrically and evenly distributed on the surface of the revetment block with the top center of the two limiting grooves close to each other and in contact with the surface of the drainage hole.
[0010] Through the above technical solution, the two limiting grooves are symmetrically and evenly distributed on the top of the revetment block. This symmetrical distribution can ensure that the barrier strip is subjected to uniform force during installation, thus ensuring the stability of the structure. The grooves are in contact with the surface of the drainage hole, which helps to achieve a compact and reasonable structure in terms of spatial layout. This allows the various components to work together. In the process of rainwater treatment, the layout of the limiting grooves may cooperate with the drainage function of the drainage hole and the functions of other components to improve the overall rainwater treatment and revetment protection effect.
[0011] As a further improvement to the above scheme, the number of the limiting blocks is set to two. The two limiting blocks are evenly distributed on the surface with respect to the bottom center of the revetment block and the barrier strip. The two limiting blocks are located inside the limiting groove.
[0012] With the above technical solution, two limiting blocks are symmetrically distributed at the bottom of the barrier strip and located in the limiting groove. This structural design can accurately position the barrier strip on the revetment block one, prevent the barrier strip from shifting during use, and ensure the normal functioning of the barrier strip, such as its function in rainwater filtration or preventing foreign objects from entering the internal structure of the revetment. At the same time, it enhances the stability of the connection between the barrier strip and the revetment block one.
[0013] As a further improvement to the above solution, the connecting strip is located at one end of the two limiting blocks that are close to each other.
[0014] Through the above technical solution, two limiting blocks are symmetrically distributed at the bottom of the barrier strip and located at the end of the connecting strip closest to the two limiting blocks, which connects the two limiting blocks and further enhances the structural stability of the limiting blocks, thereby indirectly enhancing the stability of the barrier strip on the revetment block. This helps to maintain the tight connection between the various components during the long-term use of the revetment block, ensuring the functional integrity of the entire revetment structure.
[0015] As a further improvement to the above solution, the filling block is located inside the drainage hole.
[0016] With the above technical solution, the filler block is located inside the drainage hole and can play a certain role in treating rainwater passing through the drainage hole. For example, when rainwater flows through the drainage hole, the filler block can intercept and absorb impurities in the rainwater, thereby purifying the rainwater and reducing the amount of pollutants entering the water body or the surrounding environment of the bank. At the same time, it also helps to prevent the drainage hole from being blocked by impurities and ensures the normal operation of the drainage function.
[0017] As a further improvement to the above solution, the material of the filling block is a filling sponge.
[0018] Through the above technical solution, the filling sponge, as the material for the filler block, has excellent adsorption properties. Due to its porous structure, it can effectively adsorb impurities such as dust and fine particles in rainwater, thereby improving the rainwater purification effect. Moreover, the filling sponge is relatively soft and will not damage the drainage holes. It also has a certain degree of elasticity, which allows it to maintain its shape and function when subjected to water flow impact, which is conducive to long-term and stable rainwater purification.
[0019] Compared with the prior art, the beneficial effects of this utility model are:
[0020] This invention utilizes barrier strips and filling blocks, with the revetment blocks easily spliced together via slots and latches, facilitating the construction of a revetment structure. The barrier strips and revetment blocks are stably connected, and their positioning is ensured by a limiting structure. Drainage holes promptly discharge rainwater to prevent accumulation, while the filling sponge within the drainage holes absorbs impurities in the rainwater, purifying it. Attached Figure Description
[0021] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0022] Figure 2 This is a schematic diagram of the overall connection structure between revetment block one and revetment block two of this utility model;
[0023] Figure 3 This is a schematic diagram of the overall bottom structure of this utility model;
[0024] Figure 4 This is a schematic diagram of the separation structure of the card post and card hole of this utility model;
[0025] Figure 5 This is a schematic diagram of the overall connection structure of the barrier strip of this utility model.
[0026] In the diagram: 1. Revetment Block 1; 2. Slot; 3. Block; 4. Revetment Block 2; 5. Drainage Hole; 6. Limiting Slot; 7. Hole; 8. Column; 9. Barrier Strip; 10. Limiting Block; 11. Connecting Strip; 12. Filling Block. Detailed Implementation
[0027] The present invention will be further described below with reference to the accompanying drawings and specific embodiments. It should be noted that, without conflict, the various embodiments or technical features described below can be arbitrarily combined to form new embodiments. Example
[0028] Please combine Figure 1-5 This embodiment of a porous habitat ecological revetment block that can purify rainwater includes revetment block 1, the top of revetment block 1 is provided with a slot 2, a slot block 3 is engaged inside the slot 2, and a second revetment block 4 is fixedly connected to the surface of the slot block 3.
[0029] Drainage holes 5 are provided on the top of revetment block 1. Limiting grooves 6 are provided on the top of revetment block 1. A locking hole 7 is provided at the bottom of the inner wall of the limiting groove 6. A locking post 8 is locked inside the locking hole 7. A barrier strip 9 is fixedly connected to the top of the locking post 8. A limiting block 10 is fixedly connected to the bottom of the barrier strip 9. A connecting strip 11 is fixedly connected to the surface of the limiting block 10. A filling block 12 is provided at the bottom of the connecting strip 11.
[0030] The diameters of revetment block 1 and revetment block 2 are the same.
[0031] There are two limiting grooves 6. The two limiting grooves 6 are evenly distributed on the surface with the top center of the revetment block 1 symmetrically. The ends of the two limiting grooves 6 that are close to each other are in contact with the surface of the drainage hole 5.
[0032] There are two limit blocks 10. The two limit blocks 10 are evenly distributed on the surface with the bottom center of the barrier strip 9 of the revetment block 1 symmetrically. The two limit blocks 10 are located inside the limit groove 6 respectively.
[0033] The connecting strip 11 is located at one end of the two limiting blocks 10 that are close to each other.
[0034] The filler block 12 is located inside the drain hole 5.
[0035] The material of the filling block 12 is a filling sponge.
[0036] The implementation principle of a porous habitat ecological revetment block that can purify rainwater in this application embodiment is as follows: revetment block 1 and revetment block 2 4 are connected by a snap-fit joint through a slot 2 and a snap-fit block 3. This snap-fit joint method allows the revetment blocks to be easily spliced together to form a revetment structure.
[0037] The barrier strip 9 is engaged with the locking hole 7 of the revetment block 1 via the locking post 8. The limiting block 10 is located in the limiting groove 6, which on the one hand ensures the correct positioning of the barrier strip 9 on the revetment block 1, and on the other hand, due to the number and position of the limiting groove 6, the barrier strip 9 can be stably installed on the top of the revetment block 1.
[0038] The connecting strip 11 is located at one end of the two limiting blocks 10 that are close to each other, which further enhances the structural stability of the barrier strip 9, and a filling block 12 is provided at the bottom of the connecting strip 11.
[0039] The drainage hole 5 at the top of the revetment block 1 is used for rainwater drainage. When rainwater falls on the revetment block, it will flow out through the drainage hole 5, preventing rainwater from accumulating on the surface of the revetment block.
[0040] The filling block 12 is located inside the drain hole 5. Its material is a filling sponge. The filling sponge has a certain adsorption and filtration capacity. When rainwater passes through the drain hole 5, the filling sponge can adsorb impurities in the rainwater, such as dust and some organic matter, thereby purifying the rainwater.
[0041] The above embodiments are merely preferred embodiments of this utility model and should not be construed as limiting the scope of protection of this utility model. Any non-substantial changes and substitutions made by those skilled in the art based on this utility model shall fall within the scope of protection claimed by this utility model.
Claims
1. A porous, habitable ecological revetment block capable of purifying rainwater, characterized in that: The first revetment block (1) is provided with a slot (2) on the top of the first revetment block (1), a card block (3) is engaged inside the slot (2), and a second revetment block (4) is fixedly connected to the surface of the card block (3). The top of the revetment block (1) is provided with a drainage hole (5), the top of the revetment block (1) is provided with a limiting groove (6), the bottom of the inner wall of the limiting groove (6) is provided with a locking hole (7), the inside of the locking hole (7) is fitted with a locking post (8), the top of the locking post (8) is fixedly connected with a barrier strip (9), the bottom of the barrier strip (9) is fixedly connected with a limiting block (10), the surface of the limiting block (10) is fixedly connected with a connecting strip (11), and the bottom of the connecting strip (11) is provided with a filling block (12).
2. The porous, habitable ecological revetment block capable of purifying rainwater as described in claim 1, characterized in that: The diameter of the first revetment block (1) is the same as that of the second revetment block (4).
3. The porous, habitable ecological revetment block capable of purifying rainwater as described in claim 1, characterized in that: The number of the limiting grooves (6) is set to two. The two limiting grooves (6) are evenly distributed on the surface with the top center of the revetment block (1) symmetrically. The two limiting grooves (6) are close to each other at one end and contact the surface of the drainage hole (5).
4. The porous, habitable ecological revetment block capable of purifying rainwater as described in claim 1, characterized in that: The number of the limiting blocks (10) is set to two. The two limiting blocks (10) are evenly distributed on the surface with the bottom center of the barrier strip (9) of the revetment block (1) symmetrically. The two limiting blocks (10) are located inside the limiting groove (6) respectively.
5. A porous, habitable ecological revetment block capable of purifying rainwater as described in claim 1, characterized in that: The connecting strip (11) is located at one end of the two limiting blocks (10) that are close to each other.
6. The porous, habitable ecological revetment block capable of purifying rainwater as described in claim 1, characterized in that: The filling block (12) is located inside the drain hole (5).
7. A porous, habitable ecological revetment block capable of purifying rainwater as described in claim 1, characterized in that: The filling block (12) is made of filling sponge.