CN219459747U - Strawberry seedling transplanting equipment - Google Patents

Abstract

The utility model provides strawberry seedling transplanting equipment which comprises a lifting plate (10), a positioning plate (20), a transplanting cylinder (30), a lifting assembly (40), a soil turning plate (50) and a seedling discharging assembly (60); the positioning plate (20) is arranged at the lower side of the lifting plate (10), and the positioning plate (20) is connected with the lifting plate (10) through the support column (100); a transplanting cylinder (30) is arranged at the lower side of the positioning plate (20), a conical cavity (300) is arranged in the transplanting cylinder (30), and a lifting assembly (40) is arranged at the upper end of the transplanting cylinder; the positioning plate (20) is positioned on the outer ring of the transplanting cylinder (30) and provided with a soil turning plate (50), and the soil turning plate (50) is connected with the transplanting cylinder (30) through a connecting rod (500); the conical cavity (300) is internally provided with a seedling discharging component (60). The transplanting equipment can realize soil turning, seedling discharging and soil covering in the strawberry seedling transplanting process, so that labor force is effectively saved, the transplanting efficiency of the strawberry seedlings is improved, and the survival rate of the strawberry seedlings is improved.

Description

Strawberry seedling transplanting equipment

Technical Field

The utility model relates to the technical field of transplanting seedling, in particular to strawberry seedling transplanting equipment.

Background

Strawberry is warm and cool climate, is a happy plant and has stronger shade resistance. When the illumination is strong, the strawberry has short plants, small fruits, dark colors, good quality, moderate illumination and the like; the strawberry has large fruits, light color, low sugar content and longer harvesting period; when the illumination is weaker, the strawberry has poor growth and development; it can be seen that illumination plays an important role in the growth of strawberries.

At present, in the strawberry planting process, strawberry seedlings which are cultivated in advance are transplanted into a greenhouse for dispersed planting, so that normal growth of strawberries is ensured, and the yield and quality of the strawberries are ensured. Chinese patent document CN216567078U discloses a portable transplanting device for strawberry planting, and it can make things convenient for the device to remove through the portable excavation structure that sets up, avoids the excavation structure to collide the operating personnel injury that leads to in the transportation of removing, can slowly place the transplantation seedling through the portable bearing structure that sets up, avoids transplanting seedling slip whereabouts to lead to transplanting soil landing, improves and transplants the survival rate, can make things convenient for the device to remove through the telescopic handle that sets up. However, the digging process of the transplanting device is still carried out by using manpower, labor productivity is wasted, and the digging process of the device needs the hands and feet of operators to be used together, so that the problems of complex operation, low transplanting efficiency, time consumption and labor consumption, easy tilting of strawberry seedlings and the like are caused; in addition, after the strawberry seedlings are transplanted, the soil seedlings are usually required to be planted, further the root system growth of the strawberry seedlings is ensured, the transplanting survival rate is ensured, the transplanting device is not provided with a soil covering structure, namely, the transplanting device is covered with soil manually, the soil covering efficiency is low, and labor force is wasted.

Disclosure of Invention

Aiming at the problems existing in the prior art, the utility model aims to provide the strawberry seedling transplanting equipment which realizes the soil turning, seedling discharging and soil covering of the strawberry seedling transplanting process through the cooperation of the mechanical structure, thereby effectively saving labor force, improving the transplanting efficiency of the strawberry seedling, reducing the soil turning or soil covering time and improving the transplanting survival rate of the strawberry seedling.

The aim of the utility model is achieved by the following technical scheme:

a strawberry seedling transplanting device is characterized in that: comprises a lifting plate, a positioning plate, a transplanting cylinder, a lifting assembly, a soil turning plate and a seedling discharging assembly; the positioning plate is arranged at the lower side of the lifting plate and is connected with the lifting plate through a support column; the lower side of the positioning plate is provided with a transplanting cylinder which is of a conical structure with a big upper part and a small lower part, a conical cavity is arranged in the transplanting cylinder, the upper end part of the transplanting cylinder is provided with a lifting assembly, and the lifting assembly is used for controlling the up-and-down movement of the transplanting cylinder; the positioning plate is positioned at the lower side of the outer ring of the transplanting cylinder, the soil turning plate is uniformly arranged at the lower side, the upper end of the soil turning plate is rotationally connected with the positioning plate, the inner wall of the soil turning plate is connected with the outer wall of the transplanting cylinder through a connecting rod, and the connecting rod is in sliding connection with the transplanting cylinder and is rotationally connected with the soil turning plate; the conical cavity is internally provided with a seedling discharging assembly, and the middle part of the positioning plate is provided with a seedling discharging hole corresponding to the seedling discharging assembly.

Preferably, the number of the support columns is at least two, the support columns are uniformly distributed around the axis of the positioning plate, and the upper ends and the lower ends of the support columns are fixedly connected with the bottom surface of the lifting plate and the top surface of the positioning plate respectively.

Preferably, the lifting components are two groups symmetrically arranged and are positioned on the inner side of the supporting column.

Preferably, the lifting assembly comprises a sliding sleeve and a screw rod, the bottom end of the sliding sleeve is fixedly connected with the top surface of the transplanting cylinder, which is positioned on the outer ring of the conical cavity, and the upper end of the sliding sleeve penetrates through the positioning plate and is positioned on the lower side of the lifting plate; the screw rod is coaxially arranged with the sliding sleeve, the upper end of the screw rod is rotationally connected with the bottom surface of the lifting plate, and the lower end of the screw rod is positioned in the corresponding sliding sleeve and is in threaded connection with the sliding sleeve.

Preferably, the number of the soil turning plates is 3-6.

Preferably, the lower end of the soil turning plate is provided with an arc-shaped structure which is bent inwards (namely, the side close to the transplanting cylinder).

Preferably, the seedling discharging assembly comprises two arc-shaped plates, a push rod, a connecting slide rod and a pressing rod, wherein the arc-shaped plates are symmetrically arranged about the central axis of the transplanting cylinder, the top ends of the arc-shaped plates are respectively sleeved on the outer wall of the rotating shaft, and the rotating shaft is rotationally connected with the inner wall of the transplanting cylinder; the connecting slide bar is arranged in parallel with the rotating shaft and is in sliding connection with the inner wall of the transplanting cylinder, the connecting slide bar is arranged between the two arc plates and is connected with the inner side wall of the corresponding arc plate through a push rod, and two ends of the push rod are respectively in rotary connection with the connecting slide bar and the corresponding arc plate; the upper end of the connecting slide bar is provided with a pressing rod which is parallel to the sliding sleeve (the connecting position of the pressing rod and the connecting slide bar is not interfered with the connecting position of the two ejector rods and the connecting slide bar).

Preferably, the torsion springs are uniformly arranged at the lower ends of the connecting slide bars along the axial direction of the connecting slide bars, and two ends of each torsion spring are fixedly connected with the lower end surfaces of the two ejector rods respectively.

In order to avoid the axial deviation of the pressing rod in the transplanting process, preferably, the outer wall of the upper end of the sliding sleeve is connected with the same limiting plate and the limiting plate is fixedly connected with the two sliding sleeves respectively, the pressing rod penetrates through the middle of the limiting plate and is in sliding connection with the limiting plate, and the limiting snap ring is arranged on the outer wall of the bottom surface of the limiting plate, so that the pressing rod can move downwards relative to the limiting plate and cannot move upwards relative to the limiting plate.

Preferably, the seedling discharging hole is of a conical structure with a large upper part and a small lower part, and the maximum diameter of the seedling discharging hole is not larger than the center distance between the two rotating shafts.

The utility model has the following technical effects:

according to the method, the transplanting barrel, the connecting rod, the soil turning plate and the lifting assembly are matched, the lifting assembly is used for driving the transplanting barrel to move up and down, so that the soil turning plate is unfolded and folded, the unfolded soil turning plate is used for pulling out soil, so that the strawberry seedlings are conveniently transplanted, the folded soil turning plate is used for polymerizing the soil, and the earthing of the transplanted strawberry seedlings is realized; meanwhile, the downward movement of the transplanting cylinder ensures that the strawberry seedlings are closer to the ground, so that the strawberry seedlings are prevented from tilting or tilting during throwing, and the strawberry seedlings are prevented from being damaged due to overlong throwing paths. Through the cooperation of transplanting a section of thick bamboo and seedling subassembly under, firstly protect the strawberry seedling through transplanting a section of thick bamboo soil turning in-process, secondly be convenient for put into the transplanting hole with the strawberry seedling perpendicularly, ensure the contact of soil and root, guarantee the transplanting survival rate.

In addition, the transplanting cylinder, the connecting rod, the lifting assembly, the soil turning plate and the seedling discharging assembly are matched, so that mechanized soil turning, seedling discharging and soil covering are realized, labor force is effectively saved, transplanting time is shortened, and transplanting efficiency is improved; and this application simple structure, simple operation.

Drawings

Fig. 1 is a schematic structural diagram of a strawberry seedling transplanting apparatus in an embodiment of the present utility model.

Fig. 2 is a schematic diagram of a use state of a strawberry seedling transplanting apparatus in an embodiment of the present utility model.

10, lifting plates; 100. a support column; 20. a positioning plate; 21. a seedling hole; 30. a transplanting cylinder; 300. a conical cavity; 40. a lifting assembly; 41. a sliding sleeve; 410. a limiting plate; 42. a screw; 420. a driving wheel; 50. a soil turning plate; 500. a connecting rod; 60. a seedling discharging assembly; 61. an arc-shaped plate; 610. a rotating shaft; 62. a push rod; 620. a torsion spring; 63. connecting a slide bar; 64. pressing the pressing rod.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Example 1:

as shown in fig. 1-2: a strawberry seedling transplanting device is characterized in that: comprises a lifting plate 10, a positioning plate 20, a transplanting cylinder 30, a lifting assembly 40, a soil turning plate 50 and a seedling discharging assembly 60; the positioning plate 20 is arranged at the lower side of the lifting plate 10 (the positioning plate 20 is coaxial with the lifting plate 10) and the positioning plate 20 is connected with the lifting plate 10 through the supporting column 100; the number of the support columns 100 is at least two (two support columns 100 are adopted in the embodiment), the support columns 100 are uniformly distributed around the axis of the positioning plate 20, and the upper end and the lower end of the support columns 100 are fixedly connected with the bottom surface of the lifting plate 10 and the top surface of the positioning plate 20 respectively.

The lower side of the positioning plate 20 is provided with a transplanting cylinder 30, the transplanting cylinder 30 is of a conical structure with a large upper part and a small lower part, a conical cavity 300 is arranged in the transplanting cylinder 30 (as shown in fig. 1 and 2, the cross section of the conical cavity 300 is of an equilateral trapezoid, the long bottom edge of the equilateral trapezoid is positioned on the upper side, the short bottom edge of the equilateral trapezoid is positioned on the lower side), the upper end part of the transplanting cylinder 30 is provided with a lifting assembly 40, and the up-down movement of the transplanting cylinder 30 is controlled through the lifting assembly 40; the lifting assembly 40 is two groups symmetrically arranged and is positioned at the inner side of the supporting column 100, the lifting assembly 40 comprises a sliding sleeve 41 and a screw rod 42, the bottom end of the sliding sleeve 41 is fixedly connected with the top surface of the transplanting cylinder 30 positioned at the outer ring of the conical cavity 300, and the upper end of the sliding sleeve 41 penetrates through the positioning plate 20 and is positioned at the lower side of the lifting plate 10 (the sliding sleeve 41 is in sliding connection with the positioning plate 20); the screw rod 42 is coaxially arranged with the sliding sleeve 41, the upper end of the screw rod is rotatably connected with the bottom surface of the lifting plate 10, and the lower end of the screw rod is positioned in the corresponding sliding sleeve 41 and is in threaded connection with the sliding sleeve 41. In order to avoid the sliding sleeve 41 from rotating along with the screw rod 42 and ensure that the sliding sleeve 41 moves up and down when the screw rod 42 rotates, the sliding sleeve 41 adopts a prismatic structure, specifically any one of a quadrangular prism, a pentagonal prism and a hexagonal prism, the positioning plate 20 is provided with a sliding hole with a quadrangular, pentagonal or hexagonal cross section corresponding to the sliding sleeve 41, and the sliding sleeve 41 is in sliding connection with the corresponding sliding hole.

The positioning plate 20 is located at the lower side of the outer ring of the transplanting cylinder 30, the soil turning plates 50 are uniformly arranged at the lower side of the outer ring of the transplanting cylinder 30, the upper ends of the soil turning plates 50 are rotationally connected with the positioning plate 20 through bearing seats, the number of the soil turning plates 50 is 3-6 (4 in the embodiment), and the lower ends of the soil turning plates 50 are arranged into arc-shaped structures which are bent inwards (namely, at the side close to the transplanting cylinder 30) (as shown in fig. 1 and 2). The inner wall of the soil turning plate 50 is connected with the outer wall of the transplanting cylinder 30 through a connecting rod 500, the connecting rod 500 is connected with the transplanting cylinder 30 in a sliding way (namely, the outer wall of the transplanting cylinder 30 is provided with an inclined chute corresponding to the connecting rod 500, and one side, away from the soil turning plate 50, of the connecting rod 500 is clamped in the corresponding inclined chute and is connected in a sliding way), and the connecting rod 500 is connected with the soil turning plate 50 in a rotating way through a bearing seat.

The conical cavity 300 is internally provided with a seedling discharging assembly 60, and the middle part of the positioning plate 20 is provided with a seedling discharging hole 21 corresponding to the seedling discharging assembly 60. The seedling feeding assembly 60 comprises an arc-shaped plate 61, a push rod 62, a connecting slide rod 63 and a pressing rod 64, wherein the arc-shaped plate 61 is two and symmetrically arranged about the central axis of the transplanting cylinder 30 (as shown in fig. 1 and 2, the bottom end of the arc-shaped plate 61 is of an arc-shaped structure bent towards one side close to each other), the top end of the arc-shaped plate 61 is respectively sleeved on the outer wall of a rotating shaft 610, the rotating shaft 610 is rotationally connected with the inner wall of the transplanting cylinder 30, so that the arc-shaped plate 61 rotates around the rotating shaft 610, and the front end and the rear end of the arc-shaped plate 61 are respectively in sliding contact with the inner wall of a corresponding conical cavity 300 as shown in fig. 1 and 2; the connecting slide bar 63 is arranged in parallel with the rotating shaft 610 and is in sliding connection with the inner wall of the transplanting cylinder 30 (as shown in fig. 1 and 2, vertical sliding grooves are formed in the inner walls of the middle parts of the front end and the rear end of the transplanting cylinder 30, two ends of the connecting slide bar 63 are respectively clamped into the vertical sliding grooves and are in sliding connection), the connecting slide bar 63 is arranged between two arc plates 61 and is connected with the inner side wall of the corresponding arc plate 61 through a push rod 62, two ends of the push rod 62 are respectively in rotating connection with the connecting slide bar 63 and the corresponding arc plate 61 (namely, the push rod 62 is sleeved on the outer wall of the connecting slide bar 63 and is in rotating connection, and one end of the push rod 62 far away from the connecting slide bar 63 is in rotating connection with the corresponding arc plate 61 through a bearing seat); the upper end of the connecting slide bar 63 is fixedly provided with a pressing bar 64, and the pressing bar 64 is parallel to the sliding sleeve 41 (the connection position of the pressing bar 64 and the connecting slide bar 63 is not interfered with the connection position of the two ejector rods 62 and the connecting slide bar 63); torsion springs 620 are uniformly arranged along the axial direction of the lower end of the connecting slide rod 63 (the number of the torsion springs 620 is set according to actual conditions), and two ends of the torsion springs 620 are fixedly connected with the lower end surfaces of the two ejector rods 62 respectively.

In order to avoid axial deviation of the pressing rod 64 in the transplanting process, the outer walls of the upper ends of the sliding sleeves 41 are connected through the same limiting plate 410, the limiting plates 410 are respectively and fixedly connected with the two sliding sleeves 41, the pressing rod 64 penetrates through the middle of the limiting plate 410 and is in sliding connection with the limiting plate 410, and a limiting snap ring is arranged on the outer wall of the pressing rod 64 located on the bottom surface of the limiting plate 410, so that the pressing rod 64 can move downwards relative to the limiting plate 410 and cannot move upwards relative to the limiting plate 410.

The lower seedling hole 21 has a conical structure with a large upper part and a small lower part, and the maximum diameter of the lower seedling hole 21 is not larger than the center distance between the two rotating shafts 610 (as shown in fig. 1).

Example 2:

as a further optimization of the scheme of the application, on the basis of embodiment 1, the transplanting device further comprises a moving trolley, a punching mechanism, a spraying mechanism and a soil pressing mechanism, wherein the moving trolley is provided with a rotating disc, the punching mechanism, the lifting plate 10, the spraying mechanism and the soil pressing mechanism are respectively arranged on the rotating disc, and the punching mechanism, the lifting plate 10 and the soil pressing mechanism are respectively controlled by a hydraulic device.

The punching mechanism can adopt the existing conventional punching device, the spraying mechanism can adopt the existing common spraying head, and the soil pressing mechanism adopts the annular soil pressing plate.

Working principle:

when the device is used, firstly, the whole transplanting equipment is moved to a position to be transplanted through the moving trolley, the moving trolley is self-locked and fixed, then the punching mechanism is rotated to the position to be transplanted through the rotating disc, the punching mechanism is started to punch the point with a corresponding hydraulic device, in the punching process, strawberry seedlings can be synchronously thrown into the seedling discharging holes 21 through the distance between the lifting plate 10 and the positioning plate 20, and then guided into the space between the two arc plates 61 of the conical cavity 300 through the seedling discharging holes 21 (the strawberry seedlings can be thrown manually).

After the punching is completed, the punching mechanism is reset, the lifting plate 10 is moved to a punching point position through the rotating disc, then a hydraulic device at the lifting plate 10 is started to enable the lifting plate 10 to move downwards, the lifting plate 10 drives the positioning plate 20 to move downwards through the supporting column 100, and further the transplanting cylinder 30 and the soil turning plate 50 are driven to move downwards, and the end part of the bottom end of the soil turning plate 50 is gradually inserted into the punching position; then, the hydraulic device is stopped, the screw rod 42 is started to rotate, the screw rod 4 rotates to drive the sliding sleeve 41 to move downwards, the transplanting cylinder 30 is further pushed to move downwards, the transplanting cylinder 30 pushes the soil turning plate 50 to rotate towards one end far away from the transplanting cylinder 30 through the connecting rod 500, and then soil at a punching point position is pushed to be accumulated around and a transplanting point is exposed; then, the pressing rod 64 is pressed to move downwards (pressing force can be manually applied), the pressing rod 64 drives the connecting sliding rod 63 to move downwards, the ejector rod 62 pushes the arc plates 61 to rotate towards the side far away from each other, the strawberry seedlings between the two arc plates 61 fall into punching points, then the pressing force is removed, and the two arc plates 61 are closed again due to the elastic force of the torsion spring 620; then, after the lifting plate 10 is started to rise for a certain distance, part of soil around the hole gathers towards the middle due to the action of gravity, the lifting plate 10 is started to move downwards, the bottom end of the soil turning plate 50 is inserted into the soil, the screw rod 42 is started to drive the transplanting cylinder 30 to move upwards through the sliding sleeve 41, and the soil turning plate 50 is pulled to rotate towards the side close to the transplanting cylinder 30 by the aid of the connecting rod 500, so that soil covering is completed; finally, the transplanting cylinder 30 is reset.

After seedling and earthing are completed, the spraying mechanism is moved to the punching point position to spray through the rotating disc, then the soil pressing mechanism is moved to the punching point position to compact soil, and transplanting is completed.

And finally, the mobile trolley moves to the next point position, and then the next strawberry seedling is transplanted.

Example 3:

as a further optimization of the scheme, on the basis of the embodiment 2, a strawberry seedling storage device is further arranged on the mobile trolley and used for storing strawberry seedlings to be transplanted.

Example 4:

as a further optimization of the scheme of the application, on the basis of the embodiment 1, the screw rods 42 are driven by the driving wheels 420 and the driving chains and the motors, the outer walls of the two screw rods 42 positioned on the lower side of the lifting plate 10 are respectively fixedly sleeved with the driving wheels 420, and the two driving wheels 420 are mutually corresponding and are connected by the driving chains; the upper end of one of the screws 42 is connected with the output end of a motor arranged on the lifting plate 10.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. A strawberry seedling transplanting device is characterized in that: comprises a lifting plate, a positioning plate, a transplanting cylinder, a lifting assembly, a soil turning plate and a seedling discharging assembly; the positioning plate is arranged at the lower side of the lifting plate and is connected with the lifting plate through a support column; the lower side of the positioning plate is provided with a transplanting cylinder which is of a conical structure with a big top and a small bottom, a conical cavity is arranged in the transplanting cylinder, and the upper end part of the transplanting cylinder is provided with a lifting assembly; the positioning plate is positioned at the lower side of the outer ring of the transplanting cylinder, the soil turning plate is uniformly arranged at the lower side, the upper end of the soil turning plate is rotationally connected with the positioning plate, the inner wall of the soil turning plate is connected with the outer wall of the transplanting cylinder through a connecting rod, and the connecting rod is in sliding connection with the transplanting cylinder and is rotationally connected with the soil turning plate; the conical cavity is internally provided with a seedling discharging assembly, and the middle part of the positioning plate is provided with a seedling discharging hole corresponding to the seedling discharging assembly.

2. A strawberry seedling transplanting apparatus as claimed in claim 1, wherein: the support columns are at least two and evenly distributed around the axis of the positioning plate, and the upper end and the lower end of the support columns are fixedly connected with the bottom surface of the lifting plate and the top surface of the positioning plate respectively.

3. A strawberry seedling transplanting apparatus as claimed in claim 1, wherein: the lifting components are symmetrically arranged in two groups and are positioned on the inner side of the supporting column.

4. A strawberry seedling transplanting apparatus as claimed in claim 3, wherein: the lifting assembly comprises a sliding sleeve and a screw rod, the bottom end of the sliding sleeve is fixedly connected with the top surface of the transplanting cylinder, which is positioned on the outer ring of the conical cavity, and the upper end of the sliding sleeve penetrates through the positioning plate and is positioned on the lower side of the lifting plate; the screw rod is coaxially arranged with the sliding sleeve, the upper end of the screw rod is rotationally connected with the bottom surface of the lifting plate, and the lower end of the screw rod is positioned in the corresponding sliding sleeve and is in threaded connection with the sliding sleeve.

5. A strawberry seedling transplanting apparatus as claimed in claim 4, wherein: the lower end of the soil turning plate is provided with an arc-shaped structure which is bent inwards.

6. A strawberry seedling transplanting apparatus as claimed in claim 4, wherein: the seedling discharging assembly comprises two arc-shaped plates, a push rod, a connecting slide rod and a pressing rod, wherein the arc-shaped plates are symmetrically arranged about the central axis of the transplanting cylinder, the top ends of the arc-shaped plates are respectively sleeved on the outer wall of the rotating shaft, and the rotating shaft is rotationally connected with the inner wall of the transplanting cylinder; the connecting slide bar is arranged in parallel with the rotating shaft and is in sliding connection with the inner wall of the transplanting cylinder, the connecting slide bar is arranged between the two arc plates and is connected with the inner side wall of the corresponding arc plate through a push rod, and two ends of the push rod are respectively in rotary connection with the connecting slide bar and the corresponding arc plate; the upper end of the connecting slide bar is provided with a pressing rod which is parallel to the sliding sleeve.

7. A strawberry seedling transplanting apparatus as claimed in claim 6, wherein: the outer wall of the upper end of the sliding sleeve is connected with the same limiting plate, the limiting plates are respectively fixedly connected with the two sliding sleeves, the pressing rod penetrates through the middle of the limiting plate and is in sliding connection with the limiting plate, and the outer wall of the pressing rod, which is located on the bottom surface of the limiting plate, is provided with a limiting clamping ring.