Seed raising box for landscaping
By designing a seedling box for landscaping, and utilizing air intake pipes, water supply pipes, and nozzles to backfill lost substrate, combined with a pusher roller and electric guide rail system, the problem of substrate loss caused by water spraying is solved, ensuring that plant roots are within the substrate, thus achieving normal plant growth and automation of the seedling box.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- YANGZHOU PHOENIX ISLAND ECOLOGICAL TOURISM IND CO LTD
- Filing Date
- 2025-06-05
- Publication Date
- 2026-06-09
AI Technical Summary
In the process of seed cultivation for landscaping, water spraying can cause substrate loss, leading to the exposure of plant roots and affecting normal plant growth.
Design a seedling box for landscaping, comprising a main body, planting tray, rectangular trough, inclined surface, partition plate, water pump, nozzle and one-way valve, etc. The substrate is backfilled through air suction pipe, water supply pipe and nozzle, and the substrate that does not enter with the water flow is automatically backfilled by push roller and electric guide rail system.
It effectively prevents substrate loss, ensures that plant roots are within the substrate, guarantees normal plant growth, and improves the automation and efficiency of the seedling tray.
Smart Images

Figure CN120476917B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of landscaping, and more specifically, to a seedling tray for landscaping. Background Technology
[0002] Landscape greening refers to greening projects that create a beautiful environment, improve the ecology, and enhance the quality of life by planting and arranging plants in combination with elements such as architecture, roads, and landscapes. Landscape greening includes not only the construction of public green spaces such as urban parks, flower beds, and greenways, but also private green spaces such as family courtyards and company parks.
[0003] In the process of planting plants in landscaping, planting holes need to be dug in advance according to the size of the plant roots to facilitate transplanting. When transplanting plants, the plant seeds need to be placed in a seedling tray for cultivation beforehand. When the plants grow to the stage where they can be transplanted, they are removed from the seedling tray and sent to the designated location for transplanting. Since the seeds need to be sprayed with water in the seedling tray every once in a while, each time water is sprayed onto the substrate for planting the seeds, excess water will wash away some of the substrate. Repeatedly spraying water on the seeds in the later stages of germination will lead to the loss of substrate, which will cause the plant roots to be gradually exposed outside the substrate, affecting the normal growth of the plants. Therefore, a seedling tray for landscaping is proposed. Summary of the Invention
[0004] In view of the problems existing in the prior art, the purpose of this invention is to provide a seedling tray for landscaping.
[0005] To solve the above problems, the present invention adopts the following technical solution.
[0006] A seedling tray for landscaping includes a main body, a planting tray slidably disposed inside the main body, a planting trough having multiple planting grooves filled with substrate, two sets of rectangular grooves symmetrically formed on the inner wall of the main body, two sets of inclined surfaces symmetrically formed on the bottom inner wall of the main body for guiding flow, two sets of push-out slots symmetrically formed on the inner wall of the main body, a partition plate slidably and sealed inside each set of rectangular grooves, an arc-shaped groove formed on each partition plate, multiple sets of first one-way valves fixedly installed inside each set of partition plates, a water level detector fixedly installed on the inner wall of each set of rectangular grooves, and a water pump fixedly installed on the inner wall of each set of rectangular grooves. The input and output ends of the water pump are respectively provided with a first water pipe and a second water pipe, the first water pipe being used to draw water from the rectangular grooves, and a nozzle connected to the second water pipe is also disposed inside the main body of the seedling tray.
[0007] Furthermore, the inner wall of the seedling box body is provided with equipment slots, and each set of equipment slots has a first sliding groove on its inner wall. The equipment slots are all connected to the inside of the seedling box body through the first sliding groove. A push roller is provided inside the seedling box body. Both ends of the push roller are fixedly connected to rotating rods. Each set of rotating rods is slidably disposed in the first sliding groove. The first sliding groove guides the rotating rods. An electric guide rail is fixedly installed on the inner wall of each set of equipment slots. An electric slider is slidably disposed on the electric guide rail. The electric guide rail and the electric slider are adapted to each other. Both ends of the push roller are rotatably connected to the electric slider. A reset telescopic rod is fixedly connected to the electric slider. The inner wall of the equipment slot is also provided with a second sliding groove. A straight plate is slidably disposed in the second sliding groove. The reset telescopic rod is adapted to the straight plate. The push roller is in contact with the inclined surface.
[0008] Furthermore, a gear is fixedly sleeved on the outer surface of each set of rotating rods, and a toothed plate is fixedly connected to the inner wall of each set of equipment slots, with the gear meshing with the teeth on the toothed plate.
[0009] Furthermore, the reset telescopic rod is inclined, the inclination angle of the equipment slot is the same as the inclination angle of the inclined plane, the end of the equipment slot extends vertically downward, the end of the equipment slot is rounded, the reset telescopic rod includes an outer sleeve fixedly connected to an electric slider, a first thrust spring is provided inside the outer sleeve, an inner sleeve is slidably provided inside the outer sleeve, one end of the first thrust spring is fixedly connected to the inner wall of the outer sleeve, the other end of the first thrust spring is fixedly connected to the end of the inner sleeve, and the end of the equipment slot is adapted to the inner sleeve.
[0010] Furthermore, a corrugated pipe is provided in the equipment tank. The corrugated pipe is located above the straight plate. One end of the corrugated pipe is fixedly connected to the outer surface of the outer sleeve, and the other end of the corrugated pipe is fixedly connected to the inner wall of the equipment tank. A second one-way valve is fixedly provided at the end of the corrugated pipe near the inner wall of the equipment tank, and a third one-way valve is also fixedly provided at the end of the corrugated pipe near the inner wall of the equipment tank. The third one-way valve is interconnected with the arc-shaped groove.
[0011] Furthermore, a second thrust spring is fixedly connected to the bottom of each set of rectangular grooves, and the top of the second thrust spring is fixedly connected to the bottom of the partition plate. A limit plate is also fixedly installed on the inner wall of the rectangular groove, and the limit plate makes the horizontal position height of the highest point of the partition plate the same as the horizontal position height of the water level detector.
[0012] Furthermore, an air intake pipe is fixedly inserted into the rectangular groove, and a water supply pipe is also fixedly inserted into the rectangular groove. The first water pipe is located at the input end of the water pump, and the second water pipe is located at the output end of the water pump. The bottom of the first water pipe extends into the arc-shaped groove, and the second water pipe is connected to the nozzle, which is located above the planting tray.
[0013] Furthermore, each set of rectangular troughs is connected to the interior of the seedling box body through a push-out slot, and each set of partition plates is used to block the push-out slot. The horizontal height of the lowest point of the arc-shaped trough is lower than the horizontal height of the lowest point of the inclined plane. The first one-way valve is used to send water from the inside of the seedling box body into the rectangular trough. The horizontal height of the water level detector is the same as the horizontal height of the highest point of the arc-shaped trough.
[0014] Furthermore, the size of the push groove is the same as the size of the push roller, the inclination angle of the first chute and the toothed plate is the same as the inclination angle of the inclined plane, and the toothed plate is located above the first chute, while the second chute is vertically arranged.
[0015] Furthermore, the second check valve is used for air intake within the bellows, and the third check valve is used for air exhaust from the bellows.
[0016] Compared with the prior art, the beneficial effects of the present invention are as follows:
[0017] (1) This application sets up an air suction pipe, a water supply pipe, an inclined surface inside the main body of the seedling box, a first one-way valve, a water pump and a nozzle, so that the substrate lost in the planting tray returns to the planting tray, thus achieving the purpose of backfilling the lost substrate. This can effectively prevent the plant roots from being exposed outside the substrate due to the water flow carrying away the substrate, which would affect the normal growth of the plant and effectively ensure the normal growth of the plant.
[0018] (2) By setting up a pusher roller, an electric guide rail and an electric slider, this application can also backfill the substrate that failed to enter the arc-shaped groove with the water flow after the slope moisture dried, further reducing the occurrence of the situation where the substrate inside the planting trough is lost and affects the normal growth of the plants, and further ensuring the normal growth of the plants. Attached Figure Description
[0019] Figure 1 This is a schematic diagram of the overall front structure of the present invention;
[0020] Figure 2 This is a front structural cross-sectional view of the present invention;
[0021] Figure 3 This is a left view of the rear cross-sectional structure of the present invention;
[0022] Figure 4 This is a right view of the rear cross-sectional structure of the present invention;
[0023] Figure 5 This is a side structural cross-sectional view of the present invention;
[0024] Figure 6 This is an exploded view of the structure in the equipment slot of the present invention;
[0025] Figure 7 For the present invention Figure 4 Enlarged view of the structure at point A in the middle;
[0026] Figure 8 For the present invention Figure 4 Enlarged view of the structure at point B.
[0027] Explanation of the labels in the diagram:
[0028] 1. Seedling box body; 2. Planting tray; 3. Planting trough; 4. Rectangular trough; 5. Pushing trough opening; 6. Divider plate; 7. Arc-shaped trough; 8. First one-way valve; 9. Water level detector; 10. Water pump; 11. First water pipe; 12. Second water pipe; 13. Nozzle; 14. Air suction pipe; 15. Water supply pipe; 16. Equipment trough; 17. First slide rail; 18. Pushing roller; 19. Rotating rod; 20. Electric guide rail; 21. Electric slider; 22. Reset telescopic rod; 23. Second slide rail; 24. Straight plate; 25. Gear; 26. Toothed plate; 27. Outer sleeve; 28. First thrust spring; 29. Inner sleeve; 30. Bellows; 31. Second one-way valve; 32. Third one-way valve; 33. Second thrust spring; 34. Limiting plate. Detailed Implementation
[0029] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. All other embodiments obtained by those skilled in the art based on the embodiments of the present invention without creative effort are within the scope of protection of the present invention.
[0030] Please see Figures 1 to 8 A seedling tray for landscaping includes a main body 1, a planting tray 2 slidably disposed inside the main body 1, multiple planting troughs 3 formed on the planting tray 2, the planting troughs 3 filled with substrate, two sets of rectangular grooves 4 symmetrically formed on the inner wall of the main body 1, two sets of inclined surfaces symmetrically formed on the inner wall of the bottom of the main body 1 for guiding flow, and two sets of pushing slots 5 symmetrically formed on the inner wall of the main body 1. A partition plate is slidably and sealed inside each set of rectangular grooves 4. 6. Each set of partition plates 6 has an arc-shaped groove 7. Each set of partition plates 6 has multiple sets of first one-way valves 8. Each set of rectangular grooves 4 has a water level detector 9 fixedly installed on its inner wall. Each set of rectangular grooves 4 has a water pump 10 fixedly installed on its inner wall. The input and output ends of the water pump 10 are respectively provided with a first water pipe 11 and a second water pipe 12. The first water pipe 11 is used to draw water out of the rectangular grooves 4. The seedling box body 1 is also provided with a nozzle 13, which is connected to the second water pipe 12.
[0031] An air suction pipe 14 is fixedly inserted into the rectangular groove 4, and a water supply pipe 15 is also fixedly inserted into the rectangular groove 4. The first water pipe 11 is located at the input end of the water pump 10, and the second water pipe 12 is located at the output end of the water pump 10. The bottom of the first water pipe 11 extends into the arc-shaped groove 7, and the second water pipe 12 is connected to the nozzle 13. The nozzle 13 is located above the planting tray 2.
[0032] Each set of rectangular troughs 4 is connected to the inside of the seedling box body 1 through the push slot 5. Each set of partition plates 6 is used to block the push slot 5. The height of the lowest point of the arc-shaped trough 7 is lower than the height of the lowest point of the inclined plane. The first one-way valve 8 is used to send water from the inside of the seedling box body 1 into the rectangular trough 4. The horizontal position of the water level detector 9 is the same as the horizontal position of the highest point of the arc-shaped trough 7.
[0033] When using the equipment, first remove the planting tray 2 from the main body 1 of the seedling box, then plant the seeds in the planting trough 3 of the planting tray 2, and then return the planting tray 2 to the main body 1 of the seedling box. After that, close the door of the main body 1 of the seedling box. When water is sprayed on the seeds in the later stage of germination, the excess water will carry some of the substrate in the planting trough 3 to the bottom of the main body 1 of the seedling box, and under the action of gravity, it will flow along the slope of the bottom of the main body 1 of the seedling box and remain at the very bottom of the slope. When it's time for the next water spraying, the suction pipe 14 extracts the gas from the rectangular groove 4 through the external air pump. At this time, the water and substrate at the bottom of the slope will enter the rectangular groove 4 through the first one-way valve 8 and remain in the arc groove 7 of the partition plate 6 until the first one-way valve 8 is submerged by the water in the arc groove 7. At this time, the water supply pipe 15 starts to pump water from the external water tank into the rectangular groove 4 until the water level in the rectangular groove 4 reaches the position of the water level detector 9. At this time, under the action of the external controller, the water pump 10 starts to work, and draws the water and substrate mixture in the arc groove 7 through the first water pipe 11 to the second water pipe 12, and sprays it out through the second nozzle 13, so that the substrate lost in the planting tray 2 returns to the planting tray 2, realizing the purpose of backfilling the lost substrate. This can effectively prevent the plant roots from being exposed outside the substrate due to the water flow carrying away the substrate, which would affect the normal growth of the plant and effectively ensure the normal growth of the plant.
[0034] It should be noted that the water level detector 9 is electrically connected to the data processing module, external controller and water pump 10 built into the main body 1 of the seedling box. When the water level detector 9 detects water, it will transmit the signal to the data processing module for processing. Then the data processing module will transmit the data to the external controller, so that the external controller can work and control the water pump 10 to work for a period of time to extract the liquid inside the arc-shaped tank 7.
[0035] The main body 1 of the seedling box is equipped with a data processing module, an external controller, a temperature control unit for adjusting the internal temperature of the main body 1 of the seedling box, a light unit for adjusting the light intensity inside the main body 1 of the seedling box, and an oxygen supply unit for providing oxygen of different concentrations. The air intake pipe 14 is electrically connected to the external air pump and controller, and the water supply pipe 15 is connected to the external water tank.
[0036] like Figures 1 to 4 and Figures 6 to 8 As shown, the inner wall of the seedling box body 1 is provided with equipment slots 16, and each set of equipment slots 16 has a first sliding groove 17 on its inner wall. The equipment slots 16 are all connected to the inside of the seedling box body 1 through the first sliding groove 17. The inside of the seedling box body 1 is provided with push rollers 18, and both ends of the push rollers 18 are fixedly connected to rotating rods 19. Each set of rotating rods 19 is slidably arranged in the first sliding groove 17. The first sliding groove 17 guides the rotating rods 19. The inner wall of each set of equipment slots 16 is fixedly installed with electric guide rails 20. Electric sliders 21 are slidably arranged on the electric guide rails 20. The electric guide rails 20 and electric sliders 21 are adapted to each other. Both ends of the push rollers 18 are rotatably connected to the electric sliders 21. The electric sliders 21 are fixedly connected to the reset telescopic rods 22. The inner wall of the equipment slots 16 is also provided with second sliding grooves 23. A straight plate 24 is slidably arranged in the second sliding groove 23. The reset telescopic rods 22 and straight plates 24 are adapted to each other. The push rollers 18 are in contact with the inclined surface.
[0037] The reset telescopic rod 22 is inclined, and the inclination angle of the equipment slot 16 is the same as that of the inclined plane. The end of the equipment slot 16 extends vertically downward and has a rounded corner design. The reset telescopic rod 22 includes an outer sleeve 27 fixedly connected to the electric slider 21. A first thrust spring 28 is provided inside the outer sleeve 27. An inner sleeve 29 is slidably provided inside the outer sleeve 27. One end of the first thrust spring 28 is fixedly connected to the inner wall of the outer sleeve 27, and the other end of the first thrust spring 28 is fixedly connected to the end of the inner sleeve 29. The end of the equipment slot 16 is adapted to the inner sleeve 29.
[0038] First, when water needs to be sprayed onto the plants in the planting tray 2, the electric guide rail 20 and electric slider 21 are activated by the external controller. The electric slider 21 then moves along the electric guide rail 20. Due to the guiding effect of the first groove 17 on the rotating rod 19, the electric slider 21 moves along the direction of the first groove 17 via the rotating rod 19, causing the entire push roller 18 to move along the direction of the first groove 17. As the push roller 18 moves, it pushes away the dried substrate attached to the bottom of the seedling box body 1. During this movement, the reset telescopic rod 22 moves along with the electric slider 21. Figure 3As shown, the electric guide rail 20 moves from left to right to the end of the electric guide rail 20. At this time, the reset telescopic rod 22 reaches the end of the equipment slot 16, and the inner sleeve 29 will contact the straight plate 24. Since the first thrust spring 28 is not squeezed by the equipment slot 16, it will push the straight plate 24 to move from top to bottom along the second slide 23, thereby causing the partition plate 6 to move down and the push slot 5 to open. At this time, the push roller 18 will push the substrate on the inclined surface into the arc-shaped slot 7 of the partition plate 6. Due to the shape design of the arc-shaped slot 7, the substrate falling on the partition plate 6 will slide along the inclined surface of the arc-shaped slot 7 into the interior of the arc-shaped slot 7 and mix with the water. This allows the substrate that could not enter the arc-shaped slot 7 through the first one-way valve 8 with the water flow to be backfilled and used, further reducing the situation where the substrate inside the planting trough 3 is lost and affects the normal growth of plants.
[0039] Due to the inclined setting of the reset telescopic rod 22, when the electric slider 21 on the electric guide rail 20 moves back to achieve the reset effect, the reset telescopic rod 22 will contact the rounded corner design at the end of the equipment groove 16. Under the pressure of the inner wall at the bottom of the equipment groove 16, the first thrust spring 28 retracts, the inner sleeve 29 enters the inner sleeve 27, and the entire reset telescopic rod 22 achieves the purpose of reset again, which facilitates the next operation of the push roller 18 and makes the automation level of the equipment higher.
[0040] like Figures 6 to 8 As shown, a gear 25 is fixedly sleeved on the outer surface of each set of rotating rods 19, and a toothed plate 26 is fixedly connected to the inner wall of each set of equipment slots 16. The gear 25 and the teeth on the toothed plate 26 mesh with each other.
[0041] The size of the push groove 5 is the same as the size of the push roller 18. The inclination angles of the first slide groove 17 and the toothed plate 26 are the same as the inclination angles of the inclined plane, and the toothed plate 26 is located above the first slide groove 17. The second slide groove 23 is vertically arranged.
[0042] When the electric slider 21 moves on the electric guide rail 20, since the gear plate 26 is fixed to the inner wall of the equipment slot 16, the gear 25 will move as follows: Figure 3 The rotation shown in the figure causes the rotating rod 19 and the entire push roller 18 to rotate. Since the push roller 18 moves and pushes the substrate on the inclined plane while rotating, the rotating push roller 18 will also crush the substrate that has clumped due to dryness, making it easier for the substrate to enter the arc-shaped groove 7 and mix with water, reducing the occurrence of clogging of the nozzle 13 due to incomplete mixing of substrate clumps with water.
[0043] like Figure 2 and Figure 5As shown, the bottom of each rectangular groove 4 is fixedly connected to a second thrust spring 33, and the top of the second thrust spring 33 is fixedly connected to the bottom of the partition plate 6. A limit plate 34 is also fixedly installed on the inner wall of the rectangular groove 4. The limit plate 34 makes the horizontal position height of the highest point of the partition plate 6 the same as the horizontal position height of the water level detector 9.
[0044] Due to the design of the second thrust spring 33, when the reset telescopic rod 22 separates from the straight plate 24, the partition plate 6 will spring back and move upward to achieve the reset effect, which facilitates the next cooperation with the reset telescopic rod 22. At the same time, it isolates the rectangular groove 4 from the seedling box body 1, thereby preventing water from flowing out of the rectangular groove 4 through the push slot 5 while water is supplied to the rectangular groove 4 through the water supply pipe 15, which would cause the water level detector 9 to misjudge, resulting in excessive water spraying and high humidity inside the seedling box body 1 after the water dries, thus affecting the normal growth of plants.
[0045] like Figure 3 , Figure 4 , Figure 6 , Figure 7 and Figure 8 As shown, a bellows 30 is provided in the equipment tank 16. The bellows 30 is located above the straight plate 24. One end of the bellows 30 is fixedly connected to the outer surface of the outer sleeve 27, and the other end of the bellows 30 is fixedly connected to the inner wall of the equipment tank 16. A second one-way valve 31 is fixedly provided at the end of the bellows 30 near the inner wall of the equipment tank 16, and a third one-way valve 32 is also fixedly provided at the end of the bellows 30 near the inner wall of the equipment tank 16. The third one-way valve 32 is interconnected with the arc-shaped groove 7.
[0046] The second one-way valve 31 is used for air intake in the bellows 30, and the third one-way valve 32 is used for air exhaust in the bellows 30.
[0047] When the electric slider 21 is on the electric guide rail 20 as follows Figure 3 As shown in the diagram, during the rightward movement, the entire bellows 30 is constantly compressed by the reset telescopic rod 22. The gas inside is then introduced into the arc-shaped groove 7 through the third one-way valve 32, causing the substrate submerged at the bottom of the rectangular groove 4 to be pushed up, allowing it to better mix with the water and further reducing the likelihood of substrate clogging the water nozzle 13. When the electric slider 21 moves on the electric guide rail 20 as shown... Figure 3 When the bellows 30 moves to the left to achieve the reset action shown in the diagram, the bellows 30 will draw air into the interior through the second one-way valve 31, thereby achieving the reset state of the bellows 30 and further improving the automation level of the equipment.
[0048] Instructions for use: First, remove the planting tray 2 from the main body 1 of the seedling box. Then, plant the seeds in the planting trough 3 of the planting tray 2. After spraying water on the seeds in the later stages of germination, the excess water will carry some of the substrate in the planting trough 3 to the bottom of the main body 1 of the seedling box. Under the action of gravity, it will remain at the bottom of the slope. When it is time to spray water again, the suction pipe 14 will extract the gas from the rectangular groove 4 through the external air pump. At this time, the water and substrate at the bottom of the slope will enter the rectangular groove 4 through the first one-way valve 8 and remain in the arc-shaped groove 7 of the partition plate 6 until the first one-way valve 8 is closed by the arc-shaped groove 7. When the water is submerged, the water supply pipe 15 starts to pump water from the external water tank into the rectangular trough 4 until the water level in the rectangular trough 4 reaches the position of the water level detector 9. At this time, under the action of the external controller, the water pump 10 starts to work, extracts the water and substrate mixture from the arc-shaped trough 7 and sprays it out through the second nozzle 13, so that the substrate lost in the planting tray 2 returns to the planting tray 2, realizing the purpose of backfilling the lost substrate. This can effectively prevent the plant roots from being exposed outside the substrate due to the water flow carrying away the substrate, which would affect the normal growth of the plants, and effectively ensure the normal growth of the plants.
[0049] The above description is merely a preferred embodiment of the present invention; however, the scope of protection of the present invention is not limited thereto. Any equivalent substitutions or modifications made by those skilled in the art within the scope of the technology disclosed in the present invention, based on the technical solution and its improved concepts, should be covered within the scope of protection of the present invention.
Claims
1. A seedling tray for landscaping, comprising a main body (1), wherein a planting tray (2) is slidably disposed inside the main body (1), and multiple planting troughs (3) are provided on the planting tray (2), the planting troughs (3) being filled with substrate, characterized in that: The inner wall of the seedling box body (1) is symmetrically provided with two sets of rectangular grooves (4), and the inner wall of the bottom of the seedling box body (1) is symmetrically provided with two sets of inclined surfaces, which have a guiding function. The inner wall of the seedling box body (1) is also symmetrically provided with two sets of pushing slots (5). Each set of rectangular grooves (4) is provided with a sliding seal partition plate (6), each set of partition plates (6) is provided with an arc groove (7), each set of partition plates (6) is provided with multiple sets of first one-way valves (8), each set of rectangular grooves (4) is provided with a water level detector (9) on the inner wall of each set of rectangular grooves (4), each set of rectangular grooves (4) is provided with a water pump (10) on the inner wall of each set of rectangular grooves (4), the input end and the output end of the water pump (10) are respectively provided with a first water pipe (11) and a second water pipe (12), the first water pipe (11) is used to suck out the water in the rectangular grooves (4), the seedling box body (1) is also provided with a nozzle (13), the nozzle (13) is connected to the second water pipe (12); The inner wall of the seedling box body (1) is provided with equipment slots (16), and each set of equipment slots (16) is provided with a first sliding groove (17) on its inner wall. The equipment slots (16) are all connected to the inside of the seedling box body (1) through the first sliding groove (17). The seedling box body (1) is provided with a push roller (18), and both ends of the push roller (18) are fixedly connected to rotating rods (19). Each set of rotating rods (19) is slidably disposed in the first sliding groove (17). The first sliding groove (17) plays a guiding role for the rotating rods (19). The inner wall of each set of equipment slots (16) is fixedly provided with equipment slots (16). An electric guide rail (20) is installed, and an electric slider (21) is slidably arranged on the electric guide rail (20). The electric guide rail (20) and the electric slider (21) are adapted to each other. Both ends of the push roller (18) are rotatably connected to the electric slider (21). A reset telescopic rod (22) is fixedly connected to the electric slider (21). A second sliding groove (23) is also provided on the inner wall of the equipment groove (16). A straight plate (24) is slidably arranged in the second sliding groove (23). The reset telescopic rod (22) and the straight plate (24) are adapted to each other. The push roller (18) is in contact with the inclined surface.
2. The seedling tray for landscaping as described in claim 1, characterized in that: Each set of rotating rods (19) has a gear (25) fixedly sleeved on its outer surface, and each set of equipment slots (16) has a toothed plate (26) fixedly connected to its inner wall. The gear (25) meshes with the teeth on the toothed plate (26).
3. A seedling tray for landscaping as described in claim 2, characterized in that: The reset telescopic rod (22) is inclined, the inclination angle of the equipment slot (16) is the same as the inclination angle of the inclined plane, the end of the equipment slot (16) extends vertically downward, the end of the equipment slot (16) is rounded, the reset telescopic rod (22) includes an outer sleeve (27) fixedly connected to the electric slider (21), the inner sleeve (29) is slidably arranged inside the outer sleeve (27), one end of the first thrust spring (28) is fixedly connected to the inner wall of the outer sleeve (27), the other end of the first thrust spring (28) is fixedly connected to the end of the inner sleeve (29), and the end of the equipment slot (16) is adapted to the inner sleeve (29).
4. A seedling tray for landscaping as described in claim 3, characterized in that: A corrugated pipe (30) is provided in the equipment tank (16). The corrugated pipe (30) is located above the straight plate (24). One end of the corrugated pipe (30) is fixedly connected to the outer surface of the outer sleeve (27). The other end of the corrugated pipe (30) is fixedly connected to the inner wall of the equipment tank (16). A second one-way valve (31) is fixedly provided at one end of the corrugated pipe (30) near the inner wall of the equipment tank (16). A third one-way valve (32) is also fixedly provided at one end of the corrugated pipe (30) near the inner wall of the equipment tank (16). The third one-way valve (32) is interconnected with the arc groove (7).
5. A seedling tray for landscaping as described in claim 4, characterized in that: The bottom of each rectangular groove (4) is fixedly connected to a second thrust spring (33), and the top of the second thrust spring (33) is fixedly connected to the bottom of the partition plate (6). A limit plate (34) is also fixedly installed on the inner wall of the rectangular groove (4). The limit plate (34) makes the horizontal position height of the highest point of the partition plate (6) the same as the horizontal position height of the water level detector (9).
6. A seedling tray for landscaping as described in claim 5, characterized in that: An air intake pipe (14) is fixedly inserted into the rectangular groove (4), and a water supply pipe (15) is also fixedly inserted into the rectangular groove (4). The first water pipe (11) is located at the input end of the water pump (10), and the second water pipe (12) is located at the output end of the water pump (10). The bottom of the first water pipe (11) extends into the arc-shaped groove (7), and the second water pipe (12) is connected to the nozzle (13). The nozzle (13) is located above the planting tray (2).
7. A seedling tray for landscaping as described in claim 6, characterized in that: Each set of rectangular troughs (4) is connected to the inside of the seedling box body (1) through the push slot (5). Each set of partition plates (6) is used to block the push slot (5). The height of the lowest point of the arc-shaped trough (7) is lower than the height of the lowest point of the inclined plane. The first one-way valve (8) is used to send water from the inside of the seedling box body (1) into the rectangular trough (4). The horizontal position of the water level detector (9) is the same as the horizontal position of the highest point of the arc-shaped trough (7).
8. A seedling tray for landscaping as described in claim 7, characterized in that: The size of the push slot (5) is the same as the size of the push roller (18). The inclination angles of the first chute (17) and the toothed plate (26) are the same as the inclination angles of the inclined plane. The toothed plate (26) is located above the first chute (17), and the second chute (23) is vertically arranged.
9. A seedling tray for landscaping as described in claim 8, characterized in that: The second one-way valve (31) is used for air intake in the bellows (30), and the third one-way valve (32) is used for air exhaust in the bellows (30).