Green ecological three-dimensional landscape wall
By installing windbreak shells and water-absorbing cotton structures on the landscape wall, combined with irrigation components, the problem of water evaporation caused by the ventilation holes of the landscape wall was solved, realizing the recycling of water resources and the stable growth of green plants, thus meeting the needs of ecological environment and landscape beautification.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- CHONGQING YUNTONG LANDSCAPE DECORATION DESIGN CO LTD
- Filing Date
- 2025-07-15
- Publication Date
- 2026-06-05
AI Technical Summary
The existing ventilation hole design of the landscape wall increases wind speed, increases the rate of soil moisture evaporation, and wastes water resources, failing to effectively meet the dual needs of ecological environment and landscape beautification.
Design a green ecological three-dimensional landscape wall that uses a windproof shell and water-absorbing cotton structure to slow down the wind speed around the ventilation holes. The water-absorbing cotton absorbs water vapor and condenses it into water droplets. Combined with irrigation components, it collects and recycles water resources, reduces water evaporation, and achieves water conservation.
It effectively reduces the rate of water evaporation, reduces water waste, realizes the recycling of water resources, and ensures the growth stability of green plants and the beautification effect of the landscape.
Smart Images

Figure CN224319956U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of landscape wall technology, and in particular to a green ecological three-dimensional landscape wall. Background Technology
[0002] With the acceleration of urbanization, the area of urban green space is decreasing year by year. Traditional flat landscapes can no longer meet the dual needs of ecological environment and landscape beautification. Some greening is gradually being transformed into landscape walls, which can greatly increase the amount of green space per unit area and achieve three-dimensional expansion of urban green space without occupying additional land.
[0003] To enhance the greening effect, current landscape walls often feature rectangular planting frames on their surface. To ensure the plant roots can breathe, ventilation holes are installed at the bottom of the planting frames. However, since the planting frames are usually suspended far from the ground, when the airflow passes horizontally through the bottom ventilation holes, it increases the air velocity on the soil surface, thereby accelerating the evaporation rate of soil moisture in the planting frames and causing serious waste of water resources. Therefore, we provide a green ecological three-dimensional landscape wall. Utility Model Content
[0004] This utility model provides a green ecological three-dimensional landscape wall to solve the technical problems existing in the background art.
[0005] The purpose and effect of this utility model of a green ecological three-dimensional landscape wall are achieved by the following specific technical means: a green ecological three-dimensional landscape wall includes a wall body, a planting component is provided on the front of the wall body, the planting component includes multiple planting frames provided on the front of the wall body, multiple sets of ventilation holes are opened on the bottom surface of each planting frame, a windproof shell is fixedly connected to the bottom surface of each planting frame, a ventilation groove is opened on the front of each windproof shell, and water-absorbing cotton is fixedly connected to the inner wall of each windproof shell.
[0006] The front of the wall is equipped with an irrigation component for collecting and utilizing moisture inside the windbreak shell.
[0007] Preferably, a retaining net is fixedly connected to the inner wall of each of the ventilation holes.
[0008] Preferably, a dustproof net is fixedly connected to the inner wall of each ventilation slot, and one side of the dustproof net is flush with the outer surface of the windshield.
[0009] Preferably, a sliding rod is slidably connected to the front of the planting frame, and a soil loosening rod is fixedly connected to the outer surface of the sliding rod.
[0010] Preferably, a reinforcing plate is fixedly connected to the back of each planting frame, and the rear end of each reinforcing plate is connected to the front of the wall.
[0011] Preferably, the irrigation assembly includes a collection box fixedly connected to the front of the wall, the upper surface of the collection box is connected to a delivery pipe, the delivery pipe is connected to a plurality of collection pipes arranged at equal intervals, and the top end of each collection pipe is connected to the bottom surface of the windbreak shell.
[0012] Preferably, a pump body is installed on the upper surface of the collection box, and the input end of the pump body extends into the interior of the collection box. The output end of the pump body is connected to a water delivery pipe, and the water delivery pipe is connected to a plurality of irrigation pipes arranged at equal intervals. The other end of each irrigation pipe extends into the interior of the planting frame.
[0013] Preferably, a set of equally spaced reinforcing rings are fixedly connected to the outer surface of both the conveying pipe and the water supply pipe. A support frame is fixedly connected to the outer surface of each set of reinforcing rings, and the other end of each support frame is connected to the front of the wall.
[0014] Beneficial effects:
[0015] The planting components, with their windproof shells, can shield the area around the ventilation holes, thereby slowing down the airflow around the ventilation holes and the soil surface, which reduces the rate of water evaporation. The absorbent cotton inside the windproof shells can absorb the water vapor that evaporates and condense it into water droplets, further reducing water evaporation and thus reducing water waste.
[0016] The irrigation components allow for the centralized collection of water inside the windbreak shell, which can then be used to irrigate the plants, thus achieving the recycling of water resources. The reinforcement rings and support frames work together to reinforce the delivery pipes and water supply pipes, ensuring the stability of water delivery. Attached Figure Description
[0017] Figure 1 This is a schematic diagram of the overall three-dimensional structure of this utility model.
[0018] Figure 2 This is a three-dimensional structural schematic diagram of the planting frame of this utility model from the side view.
[0019] Figure 3 This is a three-dimensional structural schematic diagram of the side sectional view of the windshield shell of this utility model.
[0020] Figure 4 This is a three-dimensional structural diagram of the soil loosening rod of this utility model.
[0021] Figure 5 This is a three-dimensional structural diagram of the collection box of this utility model.
[0022] Figure 1-5 In the diagram, the correspondence between component names and drawing numbers is as follows:
[0023] 1. Wall; 2. Planting components; 201. Planting frame; 202. Ventilation hole; 203. Windproof shell; 204. Ventilation groove; 205. Absorbent cotton; 206. Retaining net; 207. Dustproof net; 208. Slide bar; 209. Loosening bar; 210. Reinforcing plate; 3. Irrigation components; 301. Collection box; 302. Delivery pipe; 303. Collection pipe; 304. Pump body; 305. Water delivery pipe; 306. Irrigation pipe; 307. Reinforcing ring; 308. Support frame. Detailed Implementation
[0024] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present utility model. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. All other embodiments obtained by those skilled in the art based on the embodiments of the present utility model without creative effort are within the protection scope of the present utility model.
[0025] As attached Figure 1 Appendix Figure 2 With appendix Figure 3 As shown: A green ecological three-dimensional landscape wall includes a wall 1. A planting component 2 is provided on the front of the wall 1. The planting component 2 includes multiple planting frames 201 disposed on the front of the wall 1. A reinforcing plate 210 is fixedly connected to the back of each planting frame 201. The rear end of each reinforcing plate 210 is connected to the front of the wall 1. The reinforcing plate 210 connects the planting frame 201 to the wall 1, ensuring the stability of the planting frame 201 in supporting the green plants. Multiple sets of ventilation holes 202 are provided on the bottom surface of each planting frame 201 to allow soil aeration, which is beneficial to the growth of the green plants. Each of the 201 has a windproof shell 203 fixedly connected to its bottom surface. The windproof shell 203 can block the air vents 202, thereby slowing down the wind speed around them and reducing the rate of soil surface moisture evaporation. Each windproof shell 203 has a ventilation groove 204 on its front side, which allows the windproof shell 203 to be connected to the outside, thus facilitating soil respiration. Each windproof shell 203 has a water-absorbing cotton 205 fixedly connected to its inner wall. The water-absorbing cotton 205 can absorb the water vapor that evaporates inside the windproof shell 203 and condense the water vapor into water droplets, further reducing water vapor evaporation and thus reducing water waste.
[0026] As attached Figure 3As shown: Each ventilation hole 202 has a soil retaining net 206 fixedly connected to its inner wall. The soil retaining net 206 can prevent soil from falling onto the absorbent cotton 205, thereby ensuring the absorbent cotton 205's absorption effect on water vapor. Each ventilation slot 204 has a dustproof net 207 fixedly connected to its inner wall, and one side of the dustproof net 207 is flush with the outer surface of the windshield shell 203. The dustproof net 207 can block external impurities to prevent them from entering the interior of the windshield shell 203.
[0027] As attached Figure 3 With appendix Figure 4 As shown: A sliding rod 208 is slidably connected to the front of the planting frame 201. A soil loosening rod 209 is fixedly connected to the outer surface of the sliding rod 208. By pushing and pulling the sliding rod 208, the soil loosening rod 209 can be driven to push the soil, thereby achieving the effect of loosening the soil.
[0028] As attached Figure 1 With appendix Figure 5 As shown: The front of the wall 1 is provided with an irrigation component 3 for collecting and utilizing the water inside the windbreak shell 203. The irrigation component 3 includes a collection box 301 fixedly connected to the front of the wall 1. The upper surface of the collection box 301 is connected to a delivery pipe 302. The delivery pipe 302 is connected to a plurality of collection pipes 303 arranged at equal intervals. The top of each collection pipe 303 is connected to the bottom surface of the windbreak shell 203. The water inside the windbreak shell 203 will enter the delivery pipe 302 through the collection pipe 303 and eventually flow into the collection box 301, thereby completing the collection of water.
[0029] As attached Figure 5 As shown: A pump body 304 is installed on the upper surface of the collection box 301, and the input end of the pump body 304 extends into the interior of the collection box 301. The output end of the pump body 304 is connected to a water supply pipe 305, which is connected to multiple irrigation pipes 306 arranged at equal intervals. The other end of each irrigation pipe 306 extends into the interior of the planting frame 201. By utilizing the operation of the pump body 304, water can be drawn from inside the collection box 301, allowing water to be sprayed from the irrigation pipes 306 onto the green plants inside the planting frame 201, thereby... Water resources are saved. A set of equally spaced reinforcing rings 307 are fixedly connected to the outer surface of the conveying pipe 302 and the outer surface of the water supply pipe 305. A support frame 308 is fixedly connected to the outer surface of each set of reinforcing rings 307. The other end of each support frame 308 is connected to the front of the wall 1. By using the cooperation of the reinforcing rings 307 and the support frame 308, the conveying pipe 302 and the water supply pipe 305 can be connected to the wall 1, thereby ensuring the stability of water delivery by the conveying pipe 302 and the water supply pipe 305.
[0030] Working principle: When in use, the windproof shell 203 can block the wind flowing under the planting frame 201, thereby slowing down the evaporation of water. When water evaporates from the vent 202, the absorbent cotton 205 will absorb the water vapor. After a certain amount of water vapor is collected on the absorbent cotton 205, it will condense into water droplets and drip into the inside of the windproof shell 203. At the same time, the water will flow into the collection box 301 through the collection pipe 303 and the delivery pipe 302. When it is necessary to irrigate the green plants, the pump body 304 is controlled to work, the water inside the collection box 301 will be pumped out and will irrigate the green plants inside the planting frame 201 through the irrigation pipe 306, effectively reducing the waste of water resources.
Claims
1. A green ecological three-dimensional landscape wall, comprising a wall (1), characterized in that: The front of the wall (1) is provided with a planting component (2). The planting component (2) includes multiple planting frames (201) provided on the front of the wall (1). Each planting frame (201) has multiple sets of ventilation holes (202) on its bottom surface. Each planting frame (201) has a windproof shell (203) fixedly connected to its bottom surface. Each windproof shell (203) has a ventilation groove (204) on its front surface. Each windproof shell (203) has a water-absorbing cotton (205) fixedly connected to its inner wall. The front of the wall (1) is provided with an irrigation component (3) for collecting and utilizing the water inside the windbreak shell (203).
2. The green ecological three-dimensional landscape wall according to claim 1, characterized in that: Each of the ventilation holes (202) has a retaining net (206) fixedly connected to its inner wall.
3. The green ecological three-dimensional landscape wall according to claim 1, characterized in that: Each ventilation slot (204) has a dustproof net (207) fixedly connected to its inner wall, and one side of the dustproof net (207) is flush with the outer surface of the windshield shell (203).
4. The green ecological three-dimensional landscape wall according to claim 1, characterized in that: The front of the planting frame (201) is slidably connected to a slide rod (208), and a soil loosening rod (209) is fixedly connected to the outer surface of the slide rod (208).
5. The green ecological three-dimensional landscape wall according to claim 1, characterized in that: Each planting frame (201) has a reinforcing plate (210) fixedly connected to its back side, and the rear end of each reinforcing plate (210) is connected to the front side of the wall (1).
6. The green ecological three-dimensional landscape wall according to claim 1, characterized in that: The irrigation assembly (3) includes a collection box (301) fixedly connected to the front of the wall (1). The upper surface of the collection box (301) is connected to a delivery pipe (302). The delivery pipe (302) is connected to a plurality of collection pipes (303) arranged at equal distances. The top of each collection pipe (303) is connected to the bottom surface of the windproof shell (203).
7. The green ecological three-dimensional landscape wall according to claim 6, characterized in that: A pump body (304) is installed on the upper surface of the collection box (301), and the input end of the pump body (304) extends into the interior of the collection box (301). The output end of the pump body (304) is connected to a water supply pipe (305), and the water supply pipe (305) is connected to a plurality of irrigation pipes (306) arranged at equal intervals. The other end of each irrigation pipe (306) extends into the interior of the planting frame (201).
8. The green ecological three-dimensional landscape wall according to claim 6, characterized in that: The outer surface of the delivery pipe (302) and the outer surface of the water supply pipe (305) are both fixedly connected with a set of equally spaced reinforcing rings (307). The outer surface of each set of reinforcing rings (307) is fixedly connected with a support frame (308). The other end of each support frame (308) is connected to the front of the wall (1).