A sapling transport device for forestry
By designing an automatically controlled seedling transport device, which utilizes temperature detectors and a water pump system to achieve automatic water replenishment, the problem of water loss during seedling transport was solved, thereby improving the survival rate of seedlings and reducing labor intensity.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HUNAN ACAD OF FORESTRY
- Filing Date
- 2025-07-21
- Publication Date
- 2026-06-09
AI Technical Summary
Dehydration problems caused by water loss during the transportation of seedlings, especially intensified by transpiration in high-temperature environments, lead to a decrease in survival rate. Current technology relies on frequent manual watering, which increases labor intensity.
Design a seedling transportation device, including a storage box, fixing components and watering components. The device uses a temperature detector to automatically control the water pump to supply water, and sprays water through cooling water bags to achieve automatic water replenishment, avoid water accumulation and root rot, and reduce manual intervention.
Automatic water replenishment in high-temperature environments reduces labor intensity, ensures seedlings are moist and breathable, improves survival rate, avoids water waste, and prevents waterlogging and root rot.
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Figure CN224330080U_ABST
Abstract
Description
Technical Field
[0001] This application relates to the technical field of seedling transplantation, and in particular to a seedling transport device for forestry. Background Technology
[0002] In forestry production, urban greening, and ecological restoration, seedling transplantation is a crucial step. Successful transplantation highly depends on maintaining the health of the seedlings during transportation, especially their effective water retention. After being removed from their original growing environment, the seedlings' ability to absorb water is temporarily interrupted or limited, while transpiration from the trunk and leaves continues. If water loss is not effectively controlled, it will directly lead to water imbalance within the seedlings, causing physiological dehydration, which is one of the main reasons for the significant decrease in seedling survival rates after transportation.
[0003] To address the issue of seedling dehydration during transportation, the current common practice is to rely on manual, regular watering. Especially in high-temperature environments, to prevent seedlings from rapidly losing water due to increased transpiration, more frequent watering is required based on the ambient temperature (especially in high temperatures). This necessitates dedicated personnel to monitor the ambient temperature throughout the process and implement high-frequency watering, thereby increasing labor intensity. Utility Model Content
[0004] To reduce labor intensity, this application provides a seedling transportation device for forestry.
[0005] The technical solution of the seedling transportation device for forestry provided in this application is as follows:
[0006] A seedling transport device for forestry includes a storage box, a fixing component, and a watering component. The fixing component is connected to the storage box, and the watering component is partially connected to the fixing component and partially connected to the storage box. The watering component is used to water the seedlings. The fixing component includes a first fixing strap and a second fixing strap. The watering component includes a cooling water bag, a temperature detector, a water supply pipe, a water tank, a water pump, and a pumping pipe. The first fixing strap connects one end of the cooling water bag to the storage box, and the second fixing strap connects the other end of the cooling water bag to the storage box. The cooling water bag is equipped with a nozzle. The temperature detector is connected to the cooling water bag. The water pump is connected to the storage box, and the water tank is connected to the lower end of the storage box. The bottom wall of the storage box is provided with a seepage hole. The pumping pipe connects the water pump to the water tank. The water supply pipe connects the water pump to the cooling water bag. A signal transmitter is connected to the temperature detector, and a signal receiver is connected to the water pump.
[0007] By adopting the above technical solution, when the temperature detector detects that the room temperature is higher than the set value, the temperature detector sends a signal to the water pump via a signal transmitter. After receiving the signal, the signal receiver on the water pump sends water from the water tank to the water delivery pipe through the pumping pipe. The water delivery pipe then sends water to the cooling water bag through the inlet pipe. The cooling water bag then sprays water onto the saplings in the storage box through nozzles. Some of the water sprayed from the nozzles is absorbed by the saplings, while the excess water that is not absorbed drips down the stems or leaves of the saplings and eventually flows to the bottom wall of the storage box. It then seeps into the water tank through the drainage holes in the bottom wall of the storage box. The entire watering process requires no manual intervention, reducing labor intensity and ensuring timely response to the saplings' water needs even at high temperatures. At the same time, it ensures that the saplings are always in a humid but breathable and healthy environment that does not accumulate water, effectively preventing problems such as root rot caused by waterlogging.
[0008] Preferably, the water application component further includes a valve, an inlet pipe is connected to the cooling water bag, the valve is connected to the inlet pipe, and the inlet pipe is connected to the water delivery pipe.
[0009] By adopting the above technical solution, when the operator finds that there are no seedlings in the storage box, they can manually close the valve. Once the valve is closed, the water flow to the cooling water bag through the inlet pipe is cut off. This prevents the water circulation system from continuing to operate even when there are no seedlings in the storage box, thus avoiding waste of water resources.
[0010] Preferably, the outer surface of the cooling water bag is covered with a sponge layer.
[0011] By adopting the above technical solution, in order to avoid the nozzles on the cooling water bag being rigidly connected to the saplings and thus damaging them, a sponge layer is set on the cooling water bag.
[0012] Preferably, the fixing component further includes a first sliding member, which includes a first slider, a fixing block, and a first fixing screw. The storage box has a first sliding groove, the first slider is connected to the first sliding groove, a connecting rod is connected to the first slider, and the first fixing strap is connected to the connecting rod. The fixing block is connected to the first slider, and the first fixing screw connects the fixing block to the first slider. The fixing block abuts against the storage box.
[0013] By adopting the above technical solution, the first slider slides along the first groove to achieve horizontal position adjustment and adapt to seedlings of different sizes; tightening the first fixing screw makes the upper and lower end faces of the fixing block press against the edge of the first groove, and locks the slider position through static friction.
[0014] Preferably, the fixing assembly further includes a second sliding member, a rotating member, and a fixing member. The second sliding member includes a second slider. The storage box has a second sliding groove, and the second slider is connected to the second sliding groove. The rotating member includes a rotating rod and a rotating disk. The rotating rod is connected to the second slider, and the rotating disk is connected to the rotating rod. The second fixing strap is connected to the rotating rod, and the rotating rod is used to wind the second fixing strap. The fixing member is connected to the storage box, and the fixing member is used to restrict the rotation of the rotating rod on the second slider. The fixing member is also used to position the second slider on the storage box.
[0015] By adopting the above technical solution, the second slider slides along the second slide groove, and the rotating disk drives the rotating rod to wind around the second fixing belt to achieve linear control of the seedling clamping force; the fixing component synchronously restricts the rotation of the rotating rod and the displacement of the second slider to achieve bidirectional locking.
[0016] Preferably, the fixing component further includes a connector, which includes a fixing rod, a third slider, and a connecting frame. The third slider is connected in the second slide groove, the fixing rod connects the second slider and the third slider, and the connecting frame is connected to the third slider. The fixing component includes an arc-shaped positioning block, a sliding rod, and a second fixing screw. The second fixing screw is connected to the connecting frame, the arc-shaped positioning block is connected to the second fixing screw, and the sliding rod is connected to the arc-shaped positioning block. The sliding rod is slidably connected to the connecting frame so that the arc-shaped positioning block is movable. The second fixing screw drives the arc-shaped positioning block to move, so that the arc-shaped positioning block is tightly fitted with the rotating rod. The arc-shaped positioning block is used to restrict the rotation of the rotating rod.
[0017] By adopting the above technical solution, rotating the second fixed screw pushes the arc-shaped positioning block to move axially along the sliding rod. The inner curved surface of the arc-shaped positioning block is completely in contact with the outer circumference of the rotating rod, and the rotation is suppressed by the contact friction force. At the same time, the arc-shaped positioning block applies radial pressure to the second slider, increasing the frictional resistance of the second slide groove wall to achieve slider positioning.
[0018] Preferably, the rotating rod has a connecting groove, the second fixing belt passes through the connecting groove, wraps around the rotating rod, and is fixedly connected to the rest of the second fixing belt itself.
[0019] By adopting the above technical solution, the second fixing belt passes through the connecting groove and then self-wraps around the rotating rod, with its end self-fixed to the belt body, forming an anti-loosening winding structure to ensure uniform tension transmission during the winding process.
[0020] Preferably, a support rod is connected to the storage box, and a gap is provided between the side wall of the support rod and the storage box, and the second fixing strap passes through the gap between the support rod and the side wall of the storage box.
[0021] By adopting the above technical solution, the gap reserved between the support rod and the side wall of the storage box forms the guide channel of the second fixing belt, so that the fixing belt extends to the cooling water bag at an acute angle with the horizontal plane, optimizing the force direction to enhance the lateral constraint stability of the seedling.
[0022] In summary, this application includes at least one of the following beneficial technical effects:
[0023] 1. When the room temperature is too high, the temperature sensor will automatically trigger the water pump. The pump draws water from the tank into the delivery pipe, then through the inlet pipe to the cooling water bag, and finally sprays it onto the saplings in the storage box through nozzles. After the saplings absorb some water, the excess water drips to the bottom of the box and flows back into the tank through the drainage holes. The entire process is automated, reducing labor intensity, ensuring timely watering during high temperatures, preventing waterlogging and root rot, and maintaining a healthy and moist environment for the saplings.
[0024] 2. When the operator finds that there are no seedlings in the storage box, they can manually close the valve. Once the valve is closed, the water flow to the cooling water bag through the inlet pipe is cut off. This prevents the water circulation system from continuing to operate even when there are no seedlings in the storage box, thus avoiding waste of water resources.
[0025] 3. The gap between the support rod and the side wall of the storage box forms a guide channel for the second fixing belt, so that the fixing belt extends to the cooling water bag at an acute angle with the horizontal plane, optimizing the force direction to enhance the lateral constraint stability of the seedling. Attached Figure Description
[0026] Figure 1 This is a schematic diagram illustrating the overall structure in the embodiments of this application.
[0027] Figure 2 This is a schematic diagram illustrating the installation position of the first sliding member in an embodiment of this application.
[0028] Figure 3 This is a structural schematic diagram illustrating the first sliding member in an embodiment of this application.
[0029] Figure 4 This is a structural schematic diagram illustrating the second sliding member in an embodiment of this application.
[0030] Figure 5 This is a cross-sectional view used in the embodiments of this application to illustrate the rotating rod and the second fixing belt.
[0031] Figure 6 This is a partial structural schematic diagram of the water application component used in the embodiments of this application.
[0032] Explanation of reference numerals in the attached drawings: 1. Storage box; 11. First slide groove; 12. Second slide groove; 13. Support rod; 14. Drain hole; 2. Fixing assembly; 21. First sliding member; 211. First slider; 2111. First connecting ear; 2112. Second connecting ear; 2113. Connecting rod; 2114. Slot; 212. Fixing block; 213. First fixing screw; 22. First fixing strap; 23. Second sliding member; 231. Second slider; 2311. Third connecting ear; 2312. Fourth connecting ear; 24. Rotating member; 241. Rotating rod; 2411. Connecting groove 242. Rotating disk; 2421. Actuating lever; 25. Connector; 251. Fixing rod; 252. Third slider; 253. Connecting frame; 2531. Connecting groove; 26. Fixing component; 261. Arc-shaped positioning block; 262. Sliding rod; 263. Second fixing screw; 27. Second fixing belt; 3. Water application assembly; 31. Cooling water bag; 311. Nozzle; 312. Sponge layer; 32. Temperature detector; 33. Water inlet pipe; 34. Valve; 35. Water delivery pipe; 36. Water tank; 37. Water pump; 371. Battery; 38. Pumping pipe; 39. Connecting hose. Detailed Implementation
[0033] The following is in conjunction with the appendix Figure 1-6 This application will be described in further detail.
[0034] This application discloses a seedling transportation device for forestry, referring to... Figure 1 It includes a storage box 1, a fixing component 2, and a watering component 3. The fixing component 2 is installed on the storage box 1, and the watering component 3 is partially installed on the fixing component 2 and partially installed on the storage box 1. The storage box 1 is used to store seedlings, the fixing component 2 is used to press the seedlings tightly inside the storage box 1, and the watering component 3 is used to water the seedlings.
[0035] Reference Figures 1-2 The storage box 1 is also provided with a first slide groove 11, which is opened on one side wall of the storage box 1. The length direction of the first slide groove 11 is parallel to the long axis direction of the storage box 1. A support rod 13 is fixedly connected to the side wall of the storage box 1 opposite to the first slide groove 11. The axis of the support rod 13 is parallel to the long axis of the storage box 1. There is a gap between the support rod 13 and the side wall of the storage box 1. A second slide groove 12 is opened below the support rod 13. The length direction of the second slide groove 12 is parallel to the long axis direction of the storage box 1.
[0036] Reference Figures 1-3The fixing component 2 includes a first sliding member 21, a first fixing band 22, a second sliding member 23, a rotating member 24, a connecting member 25, a fixing member 26, and a second fixing band 27. The first sliding member 21 includes a first slider 211, a fixing block 212, and a first fixing screw 213. The first slider 211 is slidably connected in the first slide groove 11. The geometry of the cross-section of the first slide groove 11 is consistent with the geometry of the cross-section of the first slider 211. The first slide groove 11 constrains the first slider 211 in the first slide groove 11. The first slider 211 moves only along the length direction of the first slide groove 11. The first slider 211 is provided with a first connecting ear 2111 and a second connecting ear 2112. The first connecting ear 2111 and the second connecting ear 2112 are arranged along the long axis of the storage box 1. A connecting rod 2113 is provided between the first connecting ear 2111 and the second connecting ear 2112. One end of the connecting rod 2113 is fixedly connected to the first connecting ear 2111, and the other end of the connecting rod 2113 is fixedly connected to the second connecting ear 2112. The axis of the connecting rod 2113 is parallel to the long axis of the storage box 1. One end of the first fixing strap 22 is fixedly connected to... Connected to the connecting rod 2113, the first slider 211 has a vertically formed groove 2114. The fixing block 212 slides vertically within the groove 2114. The side walls at the upper and lower ends of the long axis of the fixing block 212 abut against the upper and lower edges of the first slide groove 11, respectively. A first threaded hole is formed on the groove wall of the groove 2114, and a second threaded hole is formed on the fixing block 212. The first threaded hole and the second threaded hole are aligned. The end of the first fixing screw 213 passes through the second threaded hole on the fixing block 212 and connects to the first slider 211. After the first slider 211 is slid to a suitable position, the first fixing screw 213 is tightened to position the first slider 211 in the first slide groove 11.
[0037] Reference Figure 1 , Figure 4 and Figure 5The second sliding member 23 includes a second slider 231, which is slidably connected in the second slide groove 12. The geometry of the cross-section of the second slide groove 12 is consistent with the geometry of the cross-section of the second slider 231. The second slide groove 12 constrains the second slider 231 within it, and the second slider 231 can only move along the length direction of the second slide groove 12. The second slider 231 is provided with a third connecting ear 2311 and a fourth connecting ear 2312, which are arranged along the long axis of the storage box 1. The rotating component 24 includes a rotating rod 241 and a rotating disk 242. The rotating rod 241 is rotatably connected to the third connecting ear 2311 and the fourth connecting ear 2312. The axis of the rotating rod 241 is parallel to the long axis of the storage box 1. The rotating disk 242 is fixedly connected to one end of the rotating rod 241. A toggle rod 2421 is also fixedly connected to the rotating disk 242. A connecting groove 2411 is provided through the rotating rod 241. The length direction of the connecting groove 2411 is parallel to the axis of the rotating rod 241. One end of the second fixing band 27 passes through the connecting groove 2411, wraps around the rotating rod 241, and is fixedly connected to the rest of the second fixing band 27. When the rotating disk 242 is shaken by the toggle rod 2421 to drive the rotating rod 241 to rotate, the rotating rod 241 winds around the second fixing band 27.
[0038] Reference Figure 1 and Figure 4 The connecting component 25 includes a fixed rod 251, a third slider 252, and a connecting frame 253. The third slider 252 is slidably connected in the second slide groove 12. The fixed rod 251 is located between the second slider 231 and the third slider 252. One end of the fixed rod 251 is connected to the second slider 231, and the other end is connected to the third slider 252. The connecting frame 253 is fixedly connected to the third slider 252. The end of the rotating rod 241 near the third slider 252 extends into the connecting frame 253, but the rotating rod 241 does not contact the connecting frame 253. The fixing component 26 includes an arc-shaped positioning block 261, a sliding rod 262, and a second fixing screw 263. The connecting frame 253 has a third threaded hole. The second fixing screw 263 is threadedly connected to the connecting frame 253. The arc-shaped positioning block 261 is rotatably connected to the end of the second fixing screw 263. The radius of curvature of the arc-shaped positioning block 261 toward the rotating rod 241 is the same as the radius of curvature of the rotating rod 241. The sliding rod 262 is fixedly connected to the arc-shaped positioning block 261, and the sliding rod 262 is also slidably connected in the connecting groove 2531.
[0039] Reference Figure 1 and Figure 4The arc-shaped positioning block 261 is driven to move by rotating the second fixing screw 263. If the arc-shaped positioning block 261 moves closer to the rotating rod 241, the arc-shaped positioning block 261 will fit tightly against the circumferential side wall of the rotating rod 241, thereby restricting the rotation of the rotating rod 241 on the second slider 231. When the arc-shaped positioning block 261 is in close contact with the rotating rod 241, it also increases the friction between the second slider 231 and the second slide groove 12, thereby positioning the second slider 231 in the second slide groove 12.
[0040] Reference Figure 1 , Figure 4 and Figure 6 In this embodiment, two sets of watering components 3 are provided, and the two sets of watering components 3 are respectively installed on two sets of fixing components 2. Taking one set of watering components 3 as an example, the watering component 3 includes a cooling water bag 31, a temperature detector 32, a valve 34, a water supply pipe 35, a water tank 36, a water pump 37, and a water suction pipe 38. One end of the cooling water bag 31 is fixedly connected to the first fixing strap 22, and the other end of the cooling water bag 31 is fixedly connected to the second fixing strap 27. The second fixing strap 27 passes through the gap between the support rod 13 and the side wall of the storage box 1 and connects to the cooling water bag 31. The purpose of this arrangement is to change the force direction of the second fixing strap 27, so that it can more effectively "hold" the seedling from the side of the storage box 1, and achieve a better overall compression effect in conjunction with the first fixing strap 22 and the cooling water bag 31. The length of the cooling water bag 31 is perpendicular to the long axis of the storage box 1. The temperature detector 32 is fixedly connected to the cooling water bag 31. A connecting hose 39 is fixedly connected inside the cooling water bag 31. The connecting hose 39 is arranged in an "S" shape inside the cooling water bag 31. Several nozzles 311 are fixedly connected to the connecting hose 39. Each nozzle 311 penetrates the wall of the cooling water bag 31. The outlet direction of the nozzles 311 is uniformly facing the bottom wall of the storage box 1. A sponge layer 312 is fixedly connected to the side of the cooling water bag 31 facing the bottom wall of the storage box 1. When the rotating rod 241 is driven to rotate by the rotating disk 242, the rotating rod 241 winds around the second fixing belt 27, thereby pressing the sapling tightly inside the storage box 1 through the cooling water bag 31. In order to avoid the nozzles 311 on the cooling water bag 31 being rigidly connected to the sapling and thus damaging the sapling, a sponge layer 312 is provided on the cooling water bag 31.
[0041] Reference Figures 1-3 Before placing the sapling in the storage box 1, the cooling water bag 31 is pushed to the end of the long axis of the storage box 1 by sliding the first slider 211 and the second slider 231. Then, the sapling is placed in the storage box 1. Next, the cooling water bag 31 is slid to the middle of the storage box 1 by sliding the first slider 211 and the second slider 231. The first slider 211 is positioned on the storage box 1 by the first fixing screw 213. Then, refer to... Figure 1 and Figure 4Then, by using the lever 2421 to shake the rotating disk 242, the rotating rod 241 is driven to rotate. The rotating rod 241 is wound around the second fixing belt 27 and tightens the cooling water bag 31, thereby pressing the seedling into the storage box 1. Then, the rotation of the rotating rod 241 is restricted by the second fixing screw 263, and the second slider 231 is also positioned on the storage box 1.
[0042] Reference Figure 1 and Figure 6 A water inlet pipe 33 is fixedly connected to one end of the cooling water bag 31 along its length. The end of the water inlet pipe 33 near the cooling water bag 31 is fixedly connected to a connecting hose 39. A valve 34 is fixedly connected to the water inlet pipe 33. A water tank 36 is fixedly connected to the lower end of the storage box 1. Several seepage holes 14 are opened on the bottom wall of the storage box 1. A water pump 37 is fixedly connected to one side of the storage box 1. In this embodiment, a battery 371 for powering itself is fixedly connected to the water pump 37. One end of the water pump pipe 38 is fixedly connected to the water pump 37, and the other end of the water pump pipe 38 is fixedly connected to the water tank 36. The end of the water pump pipe 38 extends into the water tank 36. One end of the water delivery pipe 35 is fixedly connected to the water pump 37, and the end of the water inlet pipe 33 away from the cooling water bag 31 is fixedly connected to the water delivery pipe 35.
[0043] Reference Figure 1 and Figure 6 The temperature detector 32 is equipped with a signal transmitter (not shown in the figure), and the water pump 37 is equipped with a signal receiver (not shown in the figure). The signal transmitter and signal receiver are existing technologies and will not be described in detail here. When the temperature detector 32 detects that the room temperature is higher than the set value, the temperature detector 32 sends a signal to the water pump 37 through the signal transmitter. After receiving the signal, the signal receiver on the water pump 37 transfers the water in the water tank 36 to the water delivery pipe 35 through the water pump pipe 38. The water delivery pipe 35 then transfers the water to the cooling water bag 31 through the water inlet pipe 33. Subsequently, the cooling water bag 31 sprays water onto the seedlings in the storage box 1 through the nozzle 311. Part of the water sprayed from the nozzle 311 is absorbed by the seedlings, while the excess water that is not absorbed by the seedlings drips down the stems or branches of the seedlings and eventually flows to the bottom wall of the storage box 1. Then, it seeps into the water tank 36 through the seepage hole 14 on the bottom wall of the storage box 1.
[0044] The implementation principle of a seedling transportation device for forestry in this application embodiment is as follows: After the seedlings are pressed into the storage box 1 by the fixing component 2, when the temperature detected by the temperature detector 32 is higher than the set value, the temperature detector 32 sends a water supply signal to the water pump 37. Then, the water pump 37 transfers the water in the water tank 36 to the water supply pipe 35 through the water suction pipe 38. The water supply pipe 35 then transfers the water to the cooling water bag 31 through the water inlet pipe 33. Then, the cooling water bag 31 sprays the water onto the seedlings in the storage box 1 through the nozzle 311. The excess water that is not absorbed drips down the stem or branches of the seedlings and eventually flows to the bottom wall of the storage box 1. Then, it seeps into the water tank 36 through the seepage hole 14 on the bottom wall of the storage box 1.
[0045] The above are all preferred embodiments of this application and are not intended to limit the scope of protection of this application. Therefore, all equivalent changes made in accordance with the structure, shape and principle of this application should be covered within the scope of protection of this application.
Claims
1. A seedling transport device for forestry, characterized in that: It includes a storage box (1), a fixing component (2) and a watering component (3). The fixing component (2) is connected to the storage box (1). The watering component (3) is partially connected to the fixing component (2) and partially connected to the storage box (1). The watering component (3) is used to water the seedlings. The fixing component (2) includes a first fixing strap (22) and a second fixing strap (27). The water supply component (3) includes a cooling water bag (31), a temperature detector (32), a water supply pipe (35), a water tank (36), a water pump (37), and a water suction pipe (38). The first fixing strap (22) connects one end of the cooling water bag (31) to the storage box (1), and the second fixing strap (27) connects the other end of the cooling water bag (31) to the storage box (1). The cooling water bag (31) is provided with a nozzle (311). The temperature detector (32) is connected to the cooling water bag (31), the water pump (37) is connected to the storage box (1), the water tank (36) is connected to the lower end of the storage box (1), the bottom wall of the storage box (1) is provided with a seepage hole (14), the water pump (38) connects the water pump (37) to the water tank (36), and the water delivery pipe (35) connects the water pump (37) to the cooling water bag (31). A signal transmitter is connected to the temperature detector (32), and a signal receiver is connected to the water pump (37).
2. The seedling transport device for forestry according to claim 1, characterized in that: The water supply component (3) also includes a valve (34), and the cooling water bag (31) is connected to a water inlet pipe (33). The valve (34) is connected to the water inlet pipe (33), and the water inlet pipe (33) is connected to the water delivery pipe (35).
3. A seedling transport device for forestry according to claim 1, characterized in that: The outer surface of the cooling water bag (31) is covered with a sponge layer (312).
4. A seedling transport device for forestry according to claim 1, characterized in that: The fixing component (2) further includes a first sliding member (21), which includes a first slider (211), a fixing block (212) and a first fixing screw (213). The storage box (1) is provided with a first sliding groove (11). The first slider (211) is connected to the first sliding groove (11). A connecting rod (2113) is connected to the first slider (211). The first fixing strap (22) is connected to the connecting rod (2113). The fixing block (212) is connected to the first slider (211), and the first fixing screw (213) connects the fixing block (212) to the first slider (211). The fixing block (212) abuts against the storage box (1).
5. A seedling transport device for forestry according to claim 1, characterized in that: The fixing component (2) further includes a second sliding member (23), a rotating member (24) and a fixing member (26), wherein the second sliding member (23) includes a second slider (231); The storage box (1) is provided with a second slide groove (12), and the second slider (231) is connected to the second slide groove (12). The rotating component (24) includes a rotating rod (241) and a rotating disk (242). The rotating rod (241) is connected to the second slider (231), and the rotating disk (242) is connected to the rotating rod (241). The second fixing strap (27) is connected to the rotating rod (241), and the rotating rod (241) is used to wind the second fixing strap (27). The fixing member (26) is connected to the storage box (1). The fixing member (26) is used to restrict the rotation of the rotating rod (241) on the second slider (231). The fixing member (26) is also used to position the second slider (231) on the storage box (1).
6. A seedling transport device for forestry according to claim 5, characterized in that: The fixing component (2) further includes a connector (25), which includes a fixing rod (251), a third slider (252), and a connecting frame (253). The third slider (252) is connected in the second slide groove (12), the fixing rod (251) connects the second slider (231) to the third slider (252), and the connecting frame (253) is connected to the third slider (252). The fixing component (26) includes an arc-shaped positioning block (261), a sliding rod (262), and a second fixing screw (263). The second fixing screw (263) is connected to the connecting frame (253). The arc-shaped positioning block (261) is connected to the second fixing screw (263). The sliding rod (262) is connected to the arc-shaped positioning block (261) and is slidably connected to the connecting frame (253) so that the arc-shaped positioning block (261) can move. The second fixing screw (263) drives the arc-shaped positioning block (261) to move, so that the arc-shaped positioning block (261) and the rotating rod (241) are closely fitted. The arc-shaped positioning block (261) is used to restrict the rotation of the rotating rod (241).
7. A seedling transport device for forestry according to claim 5, characterized in that: The rotating rod (241) has a connecting groove (2411), the second fixing band (27) passes through the connecting groove (2411), wraps around the rotating rod (241), and is fixedly connected to the rest of the second fixing band (27).
8. A seedling transport device for forestry according to claim 7, characterized in that: A support rod (13) is connected to the side wall of the storage box (1), and there is a gap between the support rod (13) and the side wall of the storage box (1). The second fixing strap (27) passes through the gap between the support rod (13) and the storage box (1).