A wind-driven energy storage fountain landscape
By converting wind energy into mechanical energy, the wind-powered energy storage fountain landscape solves the problem of high energy consumption in traditional fountains and achieves a continuous fountain effect without external power supply, which meets the requirements of green environmental protection.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- FUJIAN WANXIANGCHUN IND & TRADE
- Filing Date
- 2025-05-15
- Publication Date
- 2026-06-23
AI Technical Summary
Traditional fountain landscapes rely on electricity, which is energy-intensive and prone to interruption due to power outages or equipment failures, thus failing to meet the needs of green and environmentally friendly development.
The wind-powered energy storage fountain landscape uses a wind speed cup rotating frame to convert wind energy into mechanical energy, and achieves liquid pressurization and jetting through a gearbox speed-up component to form a continuous fountain effect.
It can achieve liquid pressurization and jetting without the need for an external power source, reducing energy consumption and creating a continuous and uniform fountain water feature, which is in line with the concept of green environmental protection.
Smart Images

Figure CN224389124U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of fountain landscape technology, specifically to a wind-powered energy storage fountain landscape. Background Technology
[0002] In recent years, with the acceleration of urbanization and the increasing demands of people for their living environment, landscape design has gradually become an important part of urban construction. Among them, fountains, as an important element of urban landscape, are highly favored due to their dynamic and aesthetic characteristics.
[0003] However, traditional fountain landscapes typically rely on electrically driven water pumps to achieve water circulation and spraying, which has problems such as high energy consumption, high operating costs, and dependence on external energy sources; in addition, operation may be interrupted due to power outages or equipment failures.
[0004] Against the backdrop of advocating green environmental protection and sustainable development, how to utilize renewable energy (such as wind power) to drive landscape installations has become a research hotspot. Based on this, there is a need to design a wind-powered energy storage fountain landscape to solve the problems of high energy consumption and inability to function during power outages in existing fountain landscapes. Utility Model Content
[0005] Technical Solution: A wind-powered energy storage fountain landscape includes a liquid infusion pipe with one open end and the other closed end, and nozzles evenly spaced on the liquid infusion pipe. It also includes a liquid infusion component at the open end of the liquid infusion pipe for pressurizing liquid into the pipe and spraying it through the nozzles. The liquid infusion component is connected to the output shaft of a gearbox mounted on a bracket. A rotating shaft and a connecting shaft are rotatably mounted on the top of the gearbox. The lower end of the connecting shaft passes through the gearbox and connects to its input end. A torque amplifying component is provided between the rotating shaft and the connecting shaft. A wind speed cup rotating frame is mounted on the top of the rotating shaft. The wind speed cup rotating frame rotates under wind power, causing the rotating shaft to rotate. The rotational force of the rotating shaft is transmitted to the connecting shaft through the torque amplifying component and then transmitted to the input end of the gearbox via the connecting shaft.
[0006] Furthermore, it is particularly preferred that the liquid injection assembly includes a second rotating shaft, a first connecting rod, a second connecting rod, a sliding rod, and a piston. The second rotating shaft is connected to the output shaft of the gearbox. The first connecting rod is mounted on the second rotating shaft. The end of the first connecting rod away from the second rotating shaft is rotatably connected to the second connecting rod. The end of the second connecting rod away from the first connecting rod is rotatably connected to the sliding rod. The end of the sliding rod away from the second connecting rod extends into the inner cavity of the infusion tube from the opening end, and the end of the sliding rod is connected to the piston. The piston moves horizontally inside the infusion tube.
[0007] Furthermore, it is particularly preferred that the torque amplification assembly includes a worm gear disposed below the rotating shaft, a rotating shaft rotatably mounted on the top of the gearbox via a "7"-shaped plate, a worm wheel mounted on one end of the rotating shaft and meshing with the worm gear, and a bevel gear set disposed at the other end of the rotating shaft for transmitting power from the rotating shaft to the connecting shaft.
[0008] Furthermore, it is particularly preferred that the top of the gearbox is provided with a support plate for providing stable support for the first rotating shaft, and the first rotating shaft is rotatably connected to the support plate.
[0009] Furthermore, it is particularly preferred that the piston is equipped with a one-way valve.
[0010] Furthermore, it is particularly preferred that the gearbox is a speed-increasing gearbox.
[0011] Furthermore, it is particularly preferred that the open end of the infusion tube is equipped with a filter screen.
[0012] Furthermore, it is particularly preferred that the length of the sliding rod is greater than or equal to the sum of the lengths of link one and link two.
[0013] Furthermore, it is particularly preferred that the first link, the second link, and the sliding rod are arranged in a stepped descending configuration.
[0014] Compared with the prior art, the present invention has the following advantages: 1. The present invention utilizes wind energy as a driving force to achieve liquid pressurization and injection without the need for an external power source, effectively reducing energy consumption and conforming to the concept of green and environmentally friendly development.
[0015] 2. This utility model can convert low-speed wind power into high-speed rotational motion through a speed increaser, amplify the output torque, and provide sufficient power for liquid pressurization; and through the coordinated action of connecting rod one, connecting rod two, sliding rod and piston, it can realize the periodic intake and high-pressure jetting of liquid, forming a continuous and uniform fountain water feature. Attached Figure Description
[0016] Figure 1 This is a three-dimensional structural diagram of the present invention.
[0017] Figure 2 This is a three-dimensional structural diagram of the bracket, rotating shaft 1, wind speed cup rotating frame, speed increaser and liquid injection assembly of this utility model.
[0018] Figure 3 This utility model Figure 2 A partial three-dimensional structural diagram.
[0019] Figure 4 This is a three-dimensional structural diagram of the sliding rod, infusion tube, nozzle, and filter screen of this utility model.
[0020] Figure 5This is a partial three-dimensional structural diagram of the torque amplification component of this utility model.
[0021] The above-mentioned attached drawings include the following reference numerals: 1. Support, 2. Rotating shaft one, 3. Wind speed cup rotating frame, 31. Support plate, 32. Worm gear, 33. Rotating shaft, 34. Worm wheel, 35. Bevel gear set, 36. Connecting shaft, 4. Speed increaser, 5. Rotating shaft two, 6. Connecting rod one, 7. Connecting rod two, 8. Sliding rod, 9. Infusion tube, 10. Nozzle, 11. Piston, 12. Filter screen. Detailed Implementation
[0022] To make the objectives, technical solutions, and advantages of this utility model clearer, the present utility model will be further described in detail below with reference to specific embodiments and accompanying drawings. It should be understood that these descriptions are merely exemplary and not intended to limit the scope of this utility model. Furthermore, descriptions of well-known structures and technologies are omitted in the following description to avoid unnecessarily obscuring the concept of this utility model.
[0023] Example: A wind-powered energy storage fountain landscape, such as Figures 1-5 As shown, the system includes an infusion tube 9 with one open end and the other closed end, and nozzles 10 evenly spaced on the infusion tube 9. Notably, a filter screen 12 is provided at the open end of the infusion tube 9. The filter screen 12 can effectively filter impurities in the liquid, preventing impurities from entering the infusion tube 9 and clogging the pipe or damaging the nozzles 10, thereby ensuring the long-term stable operation of the system. The system also includes a liquid injection component at the open end of the infusion tube 9 for pressurizing the liquid into the infusion tube 9 and spraying the liquid from the infusion tube 9 through the nozzles 10. The liquid injection component is connected to the output shaft of a gearbox mounted on a bracket 1. A rotating shaft 2 and a connecting shaft 36 are rotatably mounted on the top of the gearbox. A support plate 31 is provided on the top of the gearbox to provide stable support for the rotating shaft 2. The rotating shaft 2 is rotatably connected to the support plate 31. The lower end of the connecting shaft 36 passes through the gearbox and is connected to its input end. A torque amplification component is installed between the shafts. A wind speed cup rotating frame 3 is installed at the top of the shaft 2. The wind speed cup rotating frame 3 rotates under the action of wind force, causing the shaft 2 to rotate synchronously. The rotational force of the shaft 2 is decelerated and amplified by the torque amplification component before being transmitted to the connecting shaft 36 and then to the input end of the gearbox. It is worth noting that the gearbox is equipped with planetary gears and is a speed increaser 4. The shaft 2 is connected to the input shaft of the gearbox through a worm gear connection. The planetary gears inside the gearbox amplify the power torque input from the connecting shaft 36, thereby providing sufficient power for subsequent liquid pressurization. It can also convert the low-speed rotation input from the connecting shaft 36 into the high-speed rotation of the gearbox output shaft, thereby improving the energy conversion efficiency. This allows the liquid in the fountain pool to be efficiently pressed into the infusion pipe 9, thus ensuring the continuity of the fountain landscape.
[0024] Furthermore, such as Figure 2 As shown, the liquid injection assembly includes a second rotating shaft 5, a first connecting rod 6, a second connecting rod 7, a sliding rod 8, and a piston 11. The second rotating shaft 5 is connected to the output shaft of the gearbox. The first connecting rod 6 is mounted on the second rotating shaft 5. The end of the first connecting rod 6 away from the second rotating shaft 5 is rotatably connected to the second connecting rod 7. The end of the second connecting rod 7 away from the first connecting rod 6 is rotatably connected to the sliding rod 8. The end of the sliding rod 8 away from the second connecting rod 7 extends into the inner cavity of the infusion tube 9 from its open end, and the end of the sliding rod 8 is connected to the piston 11. The diameter of the piston 11 is adapted to the inner diameter of the infusion tube 9. The piston 11 moves horizontally inside the infusion tube 9. A one-way valve is provided on the piston 11. When the piston 11 moves toward the open end of the infusion tube 9, the one-way valve opens. At this time, the liquid in the fountain pool flows into the infusion tube through the one-way valve. Conversely, the one-way valve closes, thereby preventing the liquid in the infusion tube 9 from flowing back.
[0025] Furthermore, such as Figure 5 As shown, the torque amplification assembly includes a worm gear 32 disposed at the lower part of the rotating shaft 2, a rotating shaft 33 rotatably mounted on the top of the gearbox via a "7"-shaped plate, a worm wheel 34 mounted on one end of the rotating shaft 33 and meshing with the worm gear 32, and a bevel gear set 35 disposed at the other end of the rotating shaft 33 for transmitting the power of the rotating shaft 33 to the connecting shaft 36.
[0026] Furthermore, the length of the sliding rod 8 is greater than or equal to the sum of the lengths of the first connecting rod 6 and the second connecting rod 7. This setting ensures that the sliding rod 8 will not cause insufficient liquid injection due to insufficient stroke during reciprocating motion, thereby ensuring that the liquid in the infusion tube 9 can be sprayed out through the nozzle 10 to form a fountain landscape.
[0027] Furthermore, the connecting rod 6, connecting rod 7, and sliding rod 8 are arranged in a stepped manner to ensure that the infusion pipe 9 is covered by the liquid in the fountain pool, thereby facilitating the injection of the liquid in the fountain pool into the infusion pipe 9 and ensuring the effect of the fountain landscape.
[0028] In use, the wind speed cup rotating frame 3 rotates under the action of wind power, converting wind energy into mechanical energy; the rotational force of the wind speed cup rotating frame 3 is transmitted to the input shaft of the gearbox through the rotating shaft 2. Since the gearbox is a speed increaser 4, it can convert the low-speed input rotation into high-speed rotation, thereby improving energy conversion efficiency; at the same time, the speed increaser 4 can also amplify the torque of the input shaft and output it through the output shaft, thereby providing sufficient power for subsequent liquid pressurization; when the connecting rod 1 6, connecting rod 2 7 and sliding rod 8 are in the following position... Figure 2As shown, the output shaft of the gearbox drives the second shaft 5 to rotate, and the second shaft 5 drives the first connecting rod 6 to rotate circumferentially around the second shaft 5. When the first connecting rod 6 rotates 180 degrees, the second connecting rod 7 moves to directly below the first connecting rod 6, and drives the sliding rod 8 and the piston 11 mounted on the sliding rod 8 to move horizontally along the opening end of the infusion tube 9. At this time, the space inside the infusion tube 9 increases, the pressure decreases, and external liquid enters the inner cavity of the infusion tube 9 through the filter screen 12. The one-way valve on the piston 11 opens, allowing liquid to flow into the infusion tube 9. As the first connecting rod continues to rotate, the second connecting rod 7 drives the sliding rod 8 and the piston 11 mounted on the sliding rod 8 to move horizontally. The piston 11 moves from the opening end of the infusion tube 9 into the infusion tube 9. At this time, the space inside the infusion tube 9 decreases and the pressure increases, compressing the liquid and delivering it to each nozzle 10 through the high-pressure environment inside the infusion tube 9. Under the action of the high-pressure liquid, the nozzle 10 sprays the liquid out in the form of a fountain, forming a beautiful landscape effect. At this time, the one-way valve on the piston 11 closes to prevent liquid backflow. In this way, by using wind power as the driving force, through the speed increase of the gearbox, the pressurization of the liquid injection component, and the spraying of the nozzle 10, natural wind energy is converted into a dynamic water feature, thus presenting a dynamic fountain landscape effect.
[0029] The above embodiments are provided for those skilled in the art to implement or use the present invention. Those skilled in the art can make various modifications or changes to the above embodiments without departing from the inventive concept of the present invention. Therefore, the protection scope of the present invention is not limited to the above embodiments, but should be the maximum scope that conforms to the innovative features mentioned in the claims.
Claims
1. A wind energy storage fountain landscape comprising a liquid delivery pipe (9) having an open end and a closed end, and nozzles (10) installed uniformly spaced on the liquid delivery pipe (9), characterized in that, It also includes a liquid injection component provided at the opening end of the infusion tube (9) for injecting liquid into the infusion tube (9) and pressurizing the liquid in the infusion tube (9) to be sprayed out through the nozzle (10). The liquid injection component is connected to the output shaft of the gearbox mounted on the bracket (1). The top of the gearbox is rotatably provided with a rotating shaft (2) and a connecting shaft (36). The lower end of the connecting shaft (36) passes through the gearbox and is connected to its input end. A torque amplification component is provided between the rotating shaft (2) and the connecting shaft (36). A wind speed cup rotating frame (3) is installed at the top of the rotating shaft (2). The wind speed cup rotating frame (3) rotates under the action of wind force and makes the rotating shaft (2) rotate. The rotational force of the rotating shaft (2) is transmitted to the connecting shaft (36) through the torque amplification component and then transmitted to the input end of the gearbox through the connecting shaft (36).
2. A wind-powered energy-storing fountain landscape according to claim 1, characterized in that, The liquid injection assembly includes a second rotating shaft (5), a first connecting rod (6), a second connecting rod (7), a sliding rod (8), and a piston (11). The second rotating shaft (5) is connected to the output shaft of the gearbox. The first connecting rod (6) is mounted on the second rotating shaft (5). The end of the first connecting rod (6) away from the second rotating shaft (5) is rotatably connected to the second connecting rod (7). The end of the second connecting rod (7) away from the first connecting rod (6) is rotatably connected to the sliding rod (8). The end of the sliding rod (8) away from the second connecting rod (7) extends into the inner cavity of the infusion tube (9) from the opening end. The end of the sliding rod (8) is connected to the piston (11). The piston (11) moves horizontally inside the infusion tube (9).
3. A wind-powered energy-storing fountain landscape according to claim 1, characterized in that, The torque amplification assembly includes a worm (32) disposed at the lower part of the rotating shaft (2), a rotating shaft (33) rotatably mounted on the top of the gearbox via a "7"-shaped plate, a worm wheel (34) mounted on one end of the rotating shaft (33) and meshing with the worm (32), and a bevel gear set (35) disposed at the other end of the rotating shaft (33) for transmitting the power of the rotating shaft (33) to the connecting shaft (36).
4. A wind-powered energy-storing fountain landscape according to claim 1, characterized in that, The top of the gearbox is provided with a support plate (31) for providing stable support for the first shaft (2), and the first shaft (2) is rotatably connected to the support plate (31).
5. A wind-powered energy-storing fountain landscape according to claim 2, characterized in that, A one-way valve is provided on the piston (11).
6. A wind-powered energy-storing fountain landscape according to claim 3, characterized in that, The gearbox is a speed increase gearbox (4).
7. A wind-powered energy-storing fountain landscape according to claim 1, characterized in that, A filter screen (12) is provided at the open end of the infusion tube (9).
8. A wind-powered energy-storing fountain landscape according to claim 2, characterized in that, The length of the sliding rod (8) is greater than or equal to the sum of the lengths of the first link (6) and the second link (7).
9. A wind-powered energy-storing fountain landscape according to claim 2, characterized in that, Link 1 (6), Link 2 (7) and Sliding rod (8) are arranged in a stepped descending manner.