Strawberry seedling cultivation and transplanting frame

By designing a strawberry seedling cultivation and transplanting frame, and using a drive component to adjust the angle of the transplanting plate and an irrigation component to achieve uniform irrigation, the problems of insufficient light and uneven irrigation in traditional multi-layer cultivation are solved, thereby improving the survival rate and transplanting efficiency of strawberry seedlings.

CN224402386UActive Publication Date: 2026-06-26People's Government of Yishan Town, Zoucheng City

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
People's Government of Yishan Town, Zoucheng City
Filing Date
2025-06-05
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

In traditional multi-layer cultivation, problems such as seedling shading, insufficient light, and uneven irrigation affect the growth and survival rate of strawberry seedlings.

Method used

A strawberry seedling cultivation and transplanting frame was designed, comprising a drive component, a transplanting component, and an irrigation component. The angle of the transplanting plate is adjusted by the drive component to ensure that each seedling receives sufficient light. The transplanting plate and the transplanting cylinder work together to facilitate transplanting. The nozzles of the irrigation component correspond to the transplanting trough to achieve uniform irrigation.

Benefits of technology

This solved the problems of insufficient sunlight and uneven irrigation, improved the survival rate and transplanting efficiency of strawberry seedlings, and reduced the difficulty of manual operation.

✦ Generated by Eureka AI based on patent content.

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    Figure CN224402386U_ABST
Patent Text Reader

Abstract

The utility model discloses a strawberry seedling cultivation transplanting frame, include: base, the upper end fixedly connected with two supports of base, two the opposite side of support all rotatoryly connected with rotating frame, be provided with transplanting assembly between two rotating frames, the upper end of two supports is provided with irrigation assembly, one side of support is provided with drive assembly, transplanting assembly includes transplanting board and transplanting cylinder, the upper end of transplanting board is provided with a plurality of symmetrical distribution transplanting groove, the inner wall of transplanting cylinder is provided with guide groove, and transplanting cylinder sets up in the inner wall of transplanting groove, the inner wall of transplanting cylinder is provided with bearing plate, the both sides fixedly connected with guide pillar of bearing plate, one side of two guide pillars all is fixedly connected with handle. Through above -mentioned structure, solve the problem of seedling shielding, insufficient illumination and uneven irrigation in traditional multilayer cultivation, improve transplanting efficiency and seedling survival rate simultaneously.
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Description

Technical Field

[0001] This utility model relates to the field of seedling cultivation technology, and in particular to a strawberry seedling cultivation and transplanting frame. Background Technology

[0002] Strawberry seedling cultivation is a crucial step in the strawberry planting process, directly affecting the yield, quality, and growth cycle of strawberries.

[0003] During the patent application process, a search revealed a Chinese patent with patent number CN219459863U: a Codonopsis pilosula seedling transplanting and cultivation rack, comprising: a support frame and several cultivation mechanisms. Two symmetrically distributed support legs are fixedly connected to the lower surface of the support frame. Each cultivation mechanism includes a main support column, with two symmetrically distributed support rods running through one side of the main support column. The surfaces of the two support rods are jointly fitted with two symmetrically distributed load-bearing mechanisms. In this Codonopsis pilosula seedling transplanting and cultivation rack, during use, the insertion and connection between the first limiting pins and first limiting slots in the multiple cultivation mechanisms allows for easy replacement of damaged cultivation mechanisms by removing the first limiting pin from the intact cultivation mechanism and replacing it with the intact one. This solves the problem of traditional cultivation racks becoming unusable due to partial damage during prolonged use.

[0004] The above method cultivates seedlings through a multi-layered cultivation structure. However, as the seedlings grow taller over a long period of time, the upper seedlings will still block the lower seedlings to a certain extent, affecting the light and irrigation of the lower seedlings. At the same time, the upper seedlings are more inconvenient to manage, which in turn affects the seedling breeding results. Utility Model Content

[0005] The purpose of this utility model is to provide a strawberry seedling cultivation and transplanting frame to solve the problems of seedling shading, insufficient light and uneven irrigation in traditional multi-layer cultivation, while improving transplanting efficiency and seedling survival rate.

[0006] To achieve the above objectives, a strawberry seedling cultivation and transplanting frame is provided, comprising: a base, two supports fixedly connected to the upper end of the base, rotating frames rotatably connected to the opposite sides of the two supports, a transplanting component disposed between the two rotating frames, an irrigation component disposed at the upper end of the two supports, and a driving component disposed on one side of one of the supports;

[0007] The transplanting assembly includes a transplanting plate and a transplanting cylinder. Both ends of the transplanting plate are fixed with rotating shafts. The upper end of the transplanting plate has multiple symmetrically distributed transplanting grooves. The inner wall of the transplanting cylinder is provided with guide grooves, and the transplanting tube is disposed on the inner wall of the transplanting grooves. The inner wall of the transplanting cylinder is provided with a support plate. Guide pillars are fixedly connected to both sides of the support plate, and a handle is fixedly connected to one side of each of the two guide pillars.

[0008] According to the strawberry seedling cultivation and transplanting frame, the irrigation component includes a gantry frame, a water supply pipe is installed on the inner top wall of the gantry frame, a plurality of symmetrically distributed nozzles are provided on the outer side wall of the water supply pipe, a connector is fixedly connected to one end of the water supply pipe through the gantry frame, and a control valve is installed on the outer side wall of the connector.

[0009] According to the strawberry seedling cultivation and transplanting frame, the driving assembly includes a driving shell fixedly connected to one side of the frame. Gear 1 and Gear 2 are rotatably connected to the inner wall of the driving shell. A rotating rod is fixedly connected to one side of Gear 1, and a motor is fixedly connected to one side of the driving shell. The output end of the motor is fixedly connected to one side of Gear 2.

[0010] According to the strawberry seedling cultivation and transplanting frame, the end of the rotating rod away from gear one is fixedly connected to one side of the rotating frame, and gear one and gear two are meshed together.

[0011] According to the strawberry seedling cultivation and transplanting frame described above, multiple nozzles correspond to multiple transplanting troughs.

[0012] According to the strawberry seedling cultivation and transplanting frame, the ends of the two rotating shafts away from the transplanting plate pass through the rotating frame and are rotatably connected thereto, and the outer walls of the two rotating shafts are fixedly connected with blocks.

[0013] According to the strawberry seedling cultivation and transplanting rack, the bottom wall of the transplanting trough and the transplanting cylinder, as well as the surface of the supporting plate, are provided with a plurality of symmetrically distributed ventilation holes.

[0014] This utility model has the following beneficial effects:

[0015] 1. Compared with existing technologies, the rotating frame can be driven by the drive component to automatically adjust the angle of the transplanting board, so that the upper seedlings are displaced, reducing the shading of the lower seedlings and ensuring that each seedling can get enough light, thus avoiding the problem of insufficient light in traditional multi-layer cultivation.

[0016] 2. Compared with existing technologies, the combination of transplanting board and transplanting cylinder allows seedlings to be easily placed in or removed, facilitating transplantation to other locations; the combination of guide pillar and handle makes it easy for staff to quickly retrieve the support board and seedlings, reducing the difficulty of manual operation.

[0017] 3. Compared with existing technologies, the multiple nozzles of the irrigation component correspond to the transplanting trough, ensuring that each seedling receives an appropriate amount of irrigation and avoiding the unevenness problem in traditional irrigation methods. Attached Figure Description

[0018] The present invention will be further described below with reference to the accompanying drawings and embodiments;

[0019] Figure 1 This is a perspective view of a strawberry seedling cultivation and transplanting frame according to the present invention.

[0020] Figure 2 This is a three-dimensional disassembled view of the transplanting components of a strawberry seedling cultivation and transplanting frame according to this utility model;

[0021] Figure 3 This is a perspective view of the irrigation component of a strawberry seedling cultivation and transplanting frame according to the present invention;

[0022] Figure 4 This is a cross-sectional view of the drive component of a strawberry seedling cultivation and transplanting frame according to the present invention.

[0023] Legend:

[0024] 1. Base; 2. Bracket; 3. Rotating frame; 4. Transplanting assembly; 5. Irrigation assembly; 6. Drive assembly; 401. Transplanting plate; 402. Transplanting cylinder; 403. Rotating shaft; 404. Transplanting trough; 405. Guide trough; 406. Bearing plate; 407. Guide support column; 408. Handle; 501. Gantry frame; 502. Water pipe; 503. Sprinkler head; 504. Connector; 505. Control valve; 601. Drive housing; 602. Gear 1; 603. Gear 2; 604. Rotating rod; 605. Motor; 4031. Stop block. Detailed Implementation

[0025] This section will describe in detail the specific embodiments of the present utility model. The preferred embodiments of the present utility model are shown in the accompanying drawings. The purpose of the drawings is to supplement the textual description with graphics, so that people can intuitively and vividly understand each technical feature and the overall technical solution of the present utility model, but they should not be construed as limiting the scope of protection of the present utility model.

[0026] Reference Figure 1-4 This utility model embodiment provides a strawberry seedling cultivation and transplanting frame, which includes: a base 1, two supports 2 fixedly connected to the upper end of the base 1, a rotating frame 3 rotatably connected to the opposite side of the two supports 2, a transplanting component 4 between the two rotating frames 3, an irrigation component 5 at the upper end of the two supports 2, and a driving component 6 on one side of one of the supports 2.

[0027] The transplanting assembly 4 includes a transplanting plate 401 and a transplanting cylinder 402. Both ends of the transplanting plate 401 are fixed with rotating shafts 403. Multiple symmetrically distributed transplanting grooves 404 are formed at the upper end of the transplanting plate 401. A guide groove 405 is provided on the inner wall of the transplanting cylinder 402, which is situated within the inner wall of the transplanting grooves 404. A support plate 406 is provided on the inner wall of the transplanting cylinder 402. Guide pillars 407 are fixedly connected to both sides of the support plate 406, and handles 408 are fixedly connected to one side of each guide pillar 407. The transplanting assembly 4 facilitates the transplanting of seedlings.

[0028] The irrigation assembly 5 includes a gantry frame 501. A water supply pipe 502 is installed on the inner top wall of the gantry frame 501. Multiple symmetrically distributed nozzles 503 are arranged on the outer wall of the water supply pipe 502. A connector 504 is fixedly connected to one end of the water supply pipe 502, which passes through the gantry frame 501. A control valve 505 is installed on the outer wall of the connector 504. The irrigation assembly 5 achieves uniform irrigation, ensuring that each seedling receives sufficient water.

[0029] The drive assembly 6 includes a drive housing 601 fixedly connected to one side of the bracket 2. Gear 1 602 and Gear 2 603 are rotatably connected to the inner wall of the drive housing 601. A rotating rod 604 is fixedly connected to one side of Gear 1 602, and a motor 605 is fixedly connected to one side of the drive housing 601. The output end of the motor 605 is fixedly connected to one side of Gear 2 603. This allows the rotating frame 3 to rotate, facilitating the management of strawberry seedlings in the transplanting cylinder 402 at a higher position.

[0030] The end of the rotating rod 604 away from gear 602 is fixedly connected to one side of the rotating frame 3, and gear 602 and gear 603 are meshed together. Power is transmitted through the meshing connection of gear 602 and gear 603.

[0031] Multiple sprinkler heads 503 correspond to multiple transplanting troughs 404. The multiple sprinkler heads 503 ensure that each seedling receives timely irrigation after transplanting.

[0032] The ends of the two rotating shafts 403 away from the transplanting plate 401 are both inserted through the rotating frame 3 and rotatably connected to it. The outer walls of the two rotating shafts 403 are fixedly connected to the stop blocks 4031. The rotatable connection between the rotating shafts 403 and the rotating frame 3 ensures that the transplanting plate 401 always faces upwards, while the stop blocks 4031 prevent the rotating shafts 403 from falling off.

[0033] Multiple symmetrically distributed ventilation holes are provided on the bottom walls of the transplanting trough 404 and the transplanting cylinder 402, as well as on the surface of the supporting plate 406. The ventilation holes facilitate air circulation, preventing poor growth of seedling roots due to lack of oxygen, and also facilitate drainage, avoiding water accumulation that could damage the seedlings.

[0034] Working principle: In use, strawberry seedlings are planted in the transplanting cylinder 402, while the supporting plate 406 supports the seedlings. The transplanting cylinder 402 is then placed in the transplanting trough 404 on the transplanting plate 401. As the seedlings grow taller, when they become obstructed from sunlight, the motor 605 is activated to drive the gear 603 to rotate. Since gear 603 meshes with gear 602, it drives the rotating rod 604 to rotate. The rotation of the rotating rod 604 drives the rotating frame 3 to rotate, thereby displacing the highest point of the transplanting plate 401 and adjusting the angle of the transplanting plate 401 to allow the seedlings to grow taller. The seedlings are placed in a more suitable light and space position, reducing the shading of the seedlings below by the upper seedlings. It also makes it easier for staff to manage the seedlings in different positions. In addition, when the seedlings need to be transplanted, the guide support 407 can be pulled by the handle 408 to remove the support plate 406 and the seedling from the transplanting cylinder 402, making it easy to transplant to other positions. When watering the seedlings, the external water pump is connected to the connector 504. When the control valve 505 is opened, water flows from the water pipe 502 through the nozzle 503 and is sprayed out, so as to achieve uniform irrigation of each seedling.

[0035] The embodiments of the present utility model have been described in detail above with reference to the accompanying drawings. However, the present utility model is not limited to the above embodiments. Within the scope of knowledge possessed by those skilled in the art, various changes can be made without departing from the spirit of the present utility model.

Claims

1. A strawberry seedling cultivation and transplanting frame, characterized in that, include: The base (1) has two supports (2) fixedly connected to its upper end. The two supports (2) are rotatably connected to a rotating frame (3) on opposite sides. A transplanting component (4) is provided between the two rotating frames (3). A watering component (5) is provided at the upper end of the two supports (2). A driving component (6) is provided on one side of one of the supports (2). The transplanting assembly (4) includes a transplanting plate (401) and a transplanting cylinder (402). Both ends of the transplanting plate (401) are fixed with a rotating shaft (403). The upper end of the transplanting plate (401) is provided with a plurality of symmetrically distributed transplanting grooves (404). The inner wall of the transplanting cylinder (402) is provided with a guide groove (405), and the transplanting cylinder (402) is located on the inner wall of the transplanting groove (404). The inner wall of the transplanting cylinder (402) is provided with a support plate (406). The two sides of the support plate (406) are fixedly connected with guide pillars (407), and one side of each of the two guide pillars (407) is fixedly connected with a handle (408).

2. The strawberry seedling cultivation and transplanting frame according to claim 1, characterized in that, The irrigation assembly (5) includes a gantry (501), a water supply pipe (502) is installed on the inner top wall of the gantry (501), and a plurality of symmetrically distributed nozzles (503) are provided on the outer side wall of the water supply pipe (502). A connector (504) is fixedly connected to one end of the water supply pipe (502) that passes through the gantry (501), and a control valve (505) is installed on the outer side wall of the connector (504).

3. The strawberry seedling cultivation and transplanting frame according to claim 1, characterized in that, The drive assembly (6) includes a drive housing (601) fixedly connected to one side of the bracket (2). Gear 1 (602) and gear 2 (603) are rotatably connected to the inner wall of the drive housing (601). A rotating rod (604) is fixedly connected to one side of gear 1 (602). A motor (605) is fixedly connected to one side of the drive housing (601). The output end of the motor (605) is fixedly connected to one side of gear 2 (603).

4. The strawberry seedling cultivation and transplanting frame according to claim 3, characterized in that, The end of the rotating rod (604) away from the gear one (602) is fixedly connected to one side of the rotating frame (3), and the gear one (602) and gear two (603) are meshed together.

5. A strawberry seedling cultivation and transplanting frame according to claim 2, characterized in that, The plurality of nozzles (503) correspond to the plurality of transplanting troughs (404).

6. The strawberry seedling cultivation and transplanting frame according to claim 1, characterized in that, The ends of the two rotating shafts (403) away from the transplanting plate (401) pass through the rotating frame (3) and are rotatably connected thereto. The outer side walls of the two rotating shafts (403) are fixedly connected with blocks (4031).

7. A strawberry seedling cultivation and transplanting frame according to claim 1, characterized in that, The bottom wall of the transplanting trough (404) and the transplanting cylinder (402) as well as the surface of the bearing plate (406) are provided with a number of symmetrically distributed ventilation holes.