CN114698526A

CN114698526A - Device is transplanted to special trees of forestry science

Info

Publication number: CN114698526A
Application number: CN202210539649.5A
Authority: CN
Inventors: 张永芝; 王珠娜; 袁玮; 魏媛媛; 徐彦彦; 周圆; 岳睿; 代东华; 王鹏; 郭东峰; 王宏建; 董洪杨; 张慧珍; 李银娣; 李艳; 王笑阳; 陈璐
Original assignee: Zhengzhou Green Expo Park Management Center
Current assignee: Zhengzhou Green Expo Park Management Center
Priority date: 2022-05-18
Filing date: 2022-05-18
Publication date: 2022-07-05

Abstract

The invention discloses a tree transplanting device special for forestry science, and belongs to the technical field of agricultural machinery. This device is transplanted to special trees of forestry science includes lifting mechanism, still includes: a clamping mechanism; the excavating mechanism comprises two mutually-opposite excavating mechanisms, the two excavating mechanisms are symmetrically arranged on two sides of the clamping mechanism, each excavating mechanism comprises a second lead screw, a lifting plate, an arc-shaped sliding shovel and a roller, the second lead screw is vertically arranged on the lifting mechanism, the second lead screw is connected with a first power device, the lifting plate is in threaded connection with the second lead screw, the top end of the arc-shaped sliding shovel is hinged to the bottom end of the lifting plate, a roller bearing is connected to the lifting mechanism, and the rollers are abutted to the bottom end of the arc-shaped sliding shovel; and the controller is electrically connected with the lifting mechanism and the first power device. According to the tree transplanting device special for forestry science, when a tree is transplanted, the tree and the soil ball can be dug out of the soil together, so that the adaptability of the transplanted tree is improved, and the survival rate of the transplanted tree is improved.

Description

Device is transplanted to special trees of forestry science

Technical Field

The invention relates to the technical field of agricultural machinery, in particular to a tree transplanting device special for forestry science.

Background

When some gardens are under construction, in order to promote the efficiency of gardens construction, generally need some trees that the volume is great to transplant. When the trees with large volume are transplanted, some mechanical equipment is needed, and construction is convenient for constructors to construct.

Some current trees transplantation devices generally include clamping mechanism, lifting mechanism and running gear, and clamping mechanism locates in the lifting mechanism, on the running gear was located to the lifting mechanism. When transplanting trees, the trees needing to be transplanted are clamped tightly through the clamping mechanism, then the manual work is excavated, the trees are separated from the soil, then the trees are lifted through the lifting mechanism, and the excavated trees are transported through the traveling mechanism. However, the existing tree transplanting device lacks the function of digging out the trees and the soil balls from the soil together, so that the adaptability of the trees is poor after the trees are transplanted, and the survival rate of the transplanted trees is low.

Disclosure of Invention

The invention aims to overcome the problems in the prior art and provide the tree transplanting device special for forestry science, and when a tree is transplanted, the tree and a soil ball can be dug out of soil together, so that the adaptability of the transplanted tree is improved, and the survival rate of the transplanted tree is improved.

The invention provides a tree transplanting device special for forestry science, which comprises a lifting mechanism and also comprises:

the clamping mechanism is arranged in the lifting mechanism;

the excavating mechanism comprises two mutually-opposite excavating mechanisms, the two excavating mechanisms are symmetrically arranged on two sides of the clamping mechanism, the excavating mechanism comprises a second screw rod, a lifting plate, an arc-shaped sliding shovel and a roller, the second screw rod is vertically arranged on the lifting mechanism, the second screw rod is connected with a first power device, the lifting plate is in threaded connection with the second screw rod, the top end of the arc-shaped sliding shovel is hinged to the bottom end of the lifting plate, the roller bearing is connected to the lifting mechanism, and the roller is abutted to the bottom end of the arc-shaped sliding shovel;

and the controller is electrically connected with the lifting mechanism and the first power device, and is electrically connected with a power supply device.

Preferably, the lifting mechanism comprises a rotary table, a mounting plate, a first lead screw and a fork frame, the rotary table is connected with an agricultural vehicle, the mounting plate is connected with the rotary table, the first lead screw is vertically arranged on the mounting plate, the first lead screw is connected with a second power device, the second power device is electrically connected with the controller, the fork frame is in threaded connection with the first lead screw, the clamping mechanism is arranged in the fork frame, the second lead screw is vertically arranged on the fork frame, and the roller bearing is connected with the fork frame.

Preferably, the clamping mechanism comprises a connecting rod, an arc-shaped bearing plate and two arc-shaped clamping plates, the connecting rod is connected to the fork frame, the arc-shaped bearing plate is connected to the connecting rod, the two arc-shaped clamping plates are symmetrically arranged on two sides of the arc-shaped bearing plate and are hinged to the arc-shaped bearing plate, a hydraulic cylinder is hinged to each arc-shaped clamping plate, each hydraulic cylinder is hinged to the fork frame, and the two hydraulic cylinders are communicated with hydraulic control loops.

Preferably, the mounting plate is provided with a first slide rail, the first slide rail is arranged in parallel with the first lead screw, the fork frame is provided with a first sliding sleeve, and the first sliding sleeve is connected with the first slide rail in a sliding manner.

Preferably, the first sliding sleeve is further provided with a locking mechanism, the locking mechanism can be clamped on the first sliding rail, and the locking mechanism is electrically connected with the controller.

Preferably, the tunneling mechanism further comprises a second slide rail, the second slide rail is arranged in parallel with the second screw rod, the lifting plate is provided with a second sliding sleeve, and the second sliding sleeve is connected with the second slide rail in a sliding manner.

Preferably, the first screw rod is further provided with a first stress sensor, the first stress sensor is electrically connected with the controller, the first stress sensor is used for detecting a real-time stress value borne by the first screw rod, and the controller controls the second power device to act according to the real-time stress value borne by the first screw rod.

Preferably, the roller is further provided with a second stress sensor, the second stress sensor is electrically connected with the controller, the second stress sensor is used for detecting a real-time stress value borne by the roller, and the controller controls the first power device to act according to the real-time stress value borne by the roller.

Compared with the prior art, the invention has the beneficial effects that: according to the tree transplanting device special for forestry science, when a tree is transplanted, the tree and the soil ball can be dug out of the soil together, so that the adaptability of the transplanted tree is improved, and the survival rate of the transplanted tree is improved. The clamping mechanism of the device can ensure the firm degree of clamping the tree by the clamping mechanism, and prevent the tree from slipping from the clamping mechanism. Through setting up first slide rail, can be when first lead screw drive crotch motion for the crotch operation is more steady, can also prevent that the crotch from taking place to rotate the normal operating that influences this device. Through setting up locking mechanism, digging trees and earth ball out of ground at two arc smooth shovels of fork frame drive, when the trees were lifted a distance, shared the power of the vertical direction that first lead screw bore to reduce the loss of first lead screw. Through setting up the second sliding sleeve, can promote the stationarity of lifter plate motion, reduce the vibration of arc smooth shovel to reduce the damage that the vibration caused whole device, thereby promote the life of whole device. Through setting up first stress sensor, when the real-time stress value that first lead screw receives exceeded certain limit, control second power device stop rotating to prevent that first lead screw from because the atress is too big and impaired. By arranging the second stress sensor, the first power device can be controlled to stop running when the stress of the roller exceeds a certain limit, so that the roller is prevented from being damaged due to overlarge stress.

Drawings

FIG. 1 is a schematic view of the structure of the present invention;

FIG. 2 is a schematic view of the structure of the A-A surface of the present invention.

Description of reference numerals:

101. the mounting plate, 102, a rotary table, 103, a first screw rod, 104, a fork frame, 105, a clamping mechanism, 106, a second screw rod, 107, a lifting plate, 108, an arc-shaped shovel, 109, a roller, 201, a connecting rod, 202, an arc-shaped supporting plate, 203, an arc-shaped clamping plate, 204, a hydraulic cylinder, 301, a first sliding rail, 302, a first sliding sleeve, 4, a locking mechanism, 501, a second sliding rail, 502, a second sliding sleeve, 6, a first stress sensor and 7, a second stress sensor.

Detailed Description

The following detailed description of the present invention is provided in conjunction with the accompanying fig. 1 and 2, but it should be understood that the scope of the present invention is not limited to the specific embodiments. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention.

Example 1:

as shown in fig. 1 and 2, the tree transplanting device special for forestry science provided by the invention comprises a lifting mechanism, and further comprises: the lifting device comprises a clamping mechanism 105, an excavating mechanism and a controller, wherein the clamping mechanism 105 is arranged in the lifting mechanism; the excavating mechanism comprises two excavating mechanisms which are arranged opposite to each other, the two excavating mechanisms are symmetrically arranged on two sides of the clamping mechanism 105, each excavating mechanism comprises a second screw 106, a lifting plate 107, an arc-shaped sliding shovel 108 and a roller 109, the second screw 106 is vertically arranged on the lifting mechanism, the second screw 106 is connected with a first power device, the lifting plate 107 is in threaded connection with the second screw 106, the top end of the arc-shaped sliding shovel 108 is hinged to the bottom end of the lifting plate 107, the roller 109 is in bearing connection with the lifting mechanism, and the roller 109 is abutted to the bottom end of the arc-shaped sliding shovel 108; the controller is electrically connected with the lifting mechanism and the first power device, and the controller is electrically connected with a power supply device.

The working principle of example 1 will now be briefly described:

when the trees are transplanted, the agricultural vehicle is moved, the trees are placed in the lifting mechanism, then the lifting mechanism is controlled to descend through the controller, and then the trees are clamped by the clamping mechanism 105. The first power device is controlled to be opened through the controller, the first power device drives the second screw rods 106 of the two tunneling mechanisms to rotate, so that the lifting plates 107 in threaded connection with the second screw rods 106 are driven to move downwards, the arc-shaped sliding shovels 108 are driven to move downwards, the rollers 109 abut against the bottom ends of the arc-shaped sliding shovels 108, and the rollers 109 are in bearing connection with the fork frames 104, so that the arc-shaped sliding shovels 108 of the two tunneling mechanisms move downwards simultaneously to be inserted into soil, and under the action of the rollers 109, the bottom ends of the two arc-shaped sliding shovels 108 are close to each other, so that the soil at the bottom ends of trees is packed between the two arc-shaped sliding shovels 108. At this point, the lifting mechanism is controlled by the controller to raise, thereby digging the trees and soil balls out of the soil using the two arc-shaped blades 108.

According to the tree transplanting device special for forestry science, when a tree is transplanted, the tree and the soil ball can be dug out of the soil together, so that the adaptability of the transplanted tree is improved, and the survival rate of the transplanted tree is improved.

Example 2:

on the basis of embodiment 1, in order to be able to lift trees of great weight to and make things convenient for the later stage to hoist trees.

As shown in fig. 1 and 2, the lifting mechanism includes a turntable 102, a mounting plate 101, a first lead screw 103, and a fork 104, the turntable 102 is connected to an agricultural vehicle, the mounting plate 101 is connected to the turntable 102, the first lead screw 103 is vertically disposed on the mounting plate 101, the first lead screw 103 is connected to a second power device, the second power device is electrically connected to the controller, the fork 104 is in threaded connection with the first lead screw 103, the clamping mechanism 105 is disposed in the fork 104, the second lead screw 106 is vertically disposed on the fork 104, and the roller 109 is bearing-connected to the fork 104.

When the trees are transplanted, the agricultural vehicle is moved, the trees are placed in the fork frames 104, then the second power device is turned on through the controller, the second power device drives the first screw rod 103 to rotate, the fork frames 104 which are in threaded connection with the first screw rod 103 are driven to move downwards until the fork frames 104 cling to the ground, and the trees are clamped through the clamping mechanism 105. After the trees are excavated, the second power device is turned on through the controller, the fork 104 is driven by the second power device to move upwards, so that the trees and soil balls are excavated from the soil by the aid of the two arc-shaped sliding shovels 108, and then the mounting plate 101 is rotated through the rotary table 102, so that the mounting plate 101 rotates by 90 degrees together with the trees, and the trees are conveniently hoisted. Through setting up second power device and first lead screw 103, can transmit great power to can lift the trees of great weight. Through setting up revolving stage 102, can make things convenient for the later stage to hoist trees.

Example 2:

in addition to embodiment 1, in order to ensure the clamping mechanism 105 can clamp the tree firmly, the tree can be prevented from slipping out of the clamping mechanism 105.

As shown in fig. 1 and 2, the clamping mechanism 105 includes a connecting rod 201, an arc-shaped supporting plate 202, and two arc-shaped clamping plates 203, the connecting rod 201 is connected to the fork 104, the arc-shaped supporting plate 202 is connected to the connecting rod 201, the two arc-shaped clamping plates 203 are symmetrically disposed on both sides of the arc-shaped supporting plate 202 and are both hinged to the arc-shaped supporting plate 202, a hydraulic cylinder 204 is hinged to each arc-shaped clamping plate 203, each hydraulic cylinder 204 is hinged to the fork 104, and the two hydraulic cylinders 204 are both connected to a hydraulic control circuit.

When clamping a tree, the agricultural vehicle is operated to enable the arc-shaped bearing plate 202 of the clamping mechanism 105 to be attached to the side wall of the tree, and then the two hydraulic cylinders 204 are driven by the hydraulic control loop to extend, so that the two arc-shaped clamping plates 203 are driven to be close to each other, and the tree is clamped. When the tree is released, the two hydraulic cylinders 204 are driven to contract through the liquid hole loop, so that the two arc-shaped clamping plates 203 are far away from each other, and the tree is released. Clamping mechanism 105 of this device can guarantee clamping mechanism 105 and press from both sides tight firm degree to the trees, prevents that the trees from taking place to follow clamping mechanism 105 interior slippage.

As a preferable scheme, as shown in fig. 1 and 2, a first slide rail 301 is arranged on the mounting plate 101, the first slide rail 301 is arranged in parallel with the first lead screw 103, a first sliding sleeve 302 is arranged on the fork 104, and the first sliding sleeve 302 is slidably connected with the first slide rail 301. Through setting up first slide rail 301, can be when first lead screw 103 drive fork 104 moves for fork 104 moves more steadily, can also prevent that fork 104 from taking place to rotate and influence the normal operating of this device.

As a preferable scheme, as shown in fig. 1 and 2, a locking mechanism 4 is further disposed on the first sliding sleeve 302, the locking mechanism 4 can be clamped on the first sliding rail 301, and the locking mechanism 4 is electrically connected with a controller. Through setting up locking mechanism 4, dig trees and earth ball out of ground at fork 104 drive two arc smooth shovels 108, when trees were lifted a distance, utilize locking mechanism 4 to lock first sliding sleeve 302 on first slide rail 301, when trees were transported, can share the power of the vertical direction that first lead screw 103 bore to reduce the loss of first lead screw 103.

As a preferable scheme, as shown in fig. 1 and 2, the tunneling mechanism further includes a second slide rail 501, the second slide rail 501 is parallel to the second lead screw 106, a second sliding sleeve 502 is arranged on the lifting plate 107, and the second sliding sleeve 502 is slidably connected to the second slide rail 501. Through setting up second sliding sleeve 502, can promote the stationarity of lifter plate 107 motion to when arc smooth shovel 108 inserts soil, reduce the vibration of arc smooth shovel 108, thereby reduce the damage that the vibration caused whole device, thereby promote the life of whole device.

As a preferable scheme, as shown in fig. 1, a first stress sensor 6 is further disposed on the first lead screw 103, the first stress sensor 6 is electrically connected to the controller, the first stress sensor 6 is configured to detect a real-time stress value applied to the first lead screw 103, and the controller controls the second power device to operate according to the real-time stress value applied to the first lead screw 103. Through setting up first stress sensor 6, utilize first stress sensor 6 to detect the real-time stress value that first lead screw 103 receives, when the real-time stress value that first lead screw 103 receives exceeded certain limit, control second power device stop rotation to prevent that first lead screw 103 from because the atress is too big and damaging.

As a preferable scheme, as shown in fig. 1 and 2, a second stress sensor 7 is further disposed on the roller 109, the second stress sensor 7 is electrically connected with the controller, the second stress sensor 7 is configured to detect a real-time stress value applied to the roller 109, and the controller controls the first power device to operate according to the real-time stress value applied to the roller 109. By providing the second stress sensor 7, the first power unit can be controlled to stop operating when the roller 109 is stressed beyond a certain limit, thereby preventing the roller 109 from being damaged due to excessive stress.

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

Claims

1. The utility model provides a device is transplanted to special trees of forestry science, includes lifting mechanism, its characterized in that still includes:

a clamping mechanism (105) disposed within the lifting mechanism;

the excavating mechanism comprises two mutually-opposite excavating mechanisms, the two excavating mechanisms are symmetrically arranged on two sides of the clamping mechanism (105), the excavating mechanism comprises a second screw rod (106), a lifting plate (107), an arc-shaped sliding shovel (108) and a roller (109), the second screw rod (106) is vertically arranged on the lifting mechanism, the second screw rod (106) is connected with a first power device, the lifting plate (107) is in threaded connection with the second screw rod (106), the top end of the arc-shaped sliding shovel (108) is hinged to the bottom end of the lifting plate (107), the roller (109) is in bearing connection with the lifting mechanism, and the roller (109) is abutted to the bottom end of the arc-shaped sliding shovel (108);

2. The special tree transplanting device for forestry science according to claim 1, wherein the lifting mechanism comprises a rotary table (102), a mounting plate (101), a first screw rod (103) and a fork (104), the rotary table (102) is connected with an agricultural vehicle, the mounting plate (101) is connected with the rotary table (102), the first screw rod (103) is vertically arranged on the mounting plate (101), the first screw rod (103) is connected with a second power device, the second power device is electrically connected with the controller, the fork (104) is in threaded connection with the first screw rod (103), the clamping mechanism (105) is arranged in the fork (104), the second screw rod (106) is vertically arranged on the fork (104), and the roller (109) is in bearing connection with the fork (104).

3. The special tree transplanting device for forestry science according to claim 2, wherein the clamping mechanism (105) comprises a connecting rod (201), an arc-shaped bearing plate (202) and two arc-shaped clamping plates (203), the connecting rod (201) is connected to the fork (104), the arc-shaped bearing plate (202) is connected to the connecting rod (201), the two arc-shaped clamping plates (203) are symmetrically arranged on two sides of the arc-shaped bearing plate (202) and are hinged to the arc-shaped bearing plate (202), a hydraulic cylinder (204) is hinged to each arc-shaped clamping plate (203), each hydraulic cylinder (204) is hinged to the fork (104), and the two hydraulic cylinders (204) are communicated with a hydraulic control loop.

4. The special tree transplanting device for forestry science according to claim 2, wherein a first sliding rail (301) is arranged on the mounting plate (101), the first sliding rail (301) is arranged in parallel with the first lead screw (103), a first sliding sleeve (302) is arranged on the fork (104), and the first sliding sleeve (302) is slidably connected with the first sliding rail (301).

5. The special tree transplanting device for forestry science according to claim 3, wherein a locking mechanism (4) is further arranged on the first sliding sleeve (302), the locking mechanism (4) can be clamped on the first sliding rail (301), and the locking mechanism (4) is electrically connected with the controller.

6. The special tree transplanting device for forestry science according to claim 1, wherein the tunneling mechanism further comprises a second slide rail (501), the second slide rail (501) is parallel to the second lead screw (106), the lifting plate (107) is provided with a second sliding sleeve (502), and the second sliding sleeve (502) is slidably connected with the second slide rail (501).

7. The tree transplanting device special for forestry science according to claim 1, wherein the first lead screw (103) is further provided with a first stress sensor (6), the first stress sensor (6) is electrically connected with the controller, the first stress sensor (6) is used for detecting a real-time stress value borne by the first lead screw (103), and the controller controls the second power device to operate according to the real-time stress value borne by the first lead screw (103).

8. The tree transplanting device special for forestry science according to claim 1, wherein the roller (109) is further provided with a second stress sensor (7), the second stress sensor (7) is electrically connected with the controller, the second stress sensor (7) is used for detecting a real-time stress value borne by the roller (109), and the controller controls the first power device to operate according to the real-time stress value borne by the roller (109).