CN111567257B - Spherical clipping machine for spherical plants - Google Patents

Abstract

The invention discloses a spherical trimmer for spherical plants, which comprises a bottom mounting base plate and an auxiliary semi-annular shell, wherein a mounting plate and a main longitudinal supporting rod are mounted on the upper surface of the bottom mounting base plate, the top of the main longitudinal supporting rod is provided with a main semi-annular shell in an integrated structure, and the bottom of the top end of the main semi-annular shell is provided with a main longitudinal discharge pipeline in an integrated structure. The invention utilizes the kinetic energy generated by high-pressure air to drive each rotary blade to rotate, and can blow and clean the surface of the trimmed fallen leaves, thereby improving the utilization rate of the kinetic energy.

Description

Spherical clipping machine for spherical plants

Technical Field

The invention relates to the technical field of planting of spherical plants, in particular to a spherical trimmer for spherical plants.

Background

At present, the existing spherical trimmer has low utilization rate of kinetic energy, and the function generated by the kinetic energy is single.

Disclosure of Invention

The present invention is directed to a spherical trimmer for spherical plants to solve the above problems.

In order to achieve the purpose, the invention provides the following technical scheme: a spherical trimmer for spherical plants comprises a bottom mounting base plate and an auxiliary semi-annular shell, wherein a mounting plate and a main longitudinal supporting rod are mounted on the upper surface of the bottom mounting base plate, a main semi-annular shell of an integrated structure is arranged at the top of the main longitudinal supporting rod, a main longitudinal discharge pipeline of an integrated structure is arranged at the bottom of the top end of the main semi-annular shell, a main annular pipeline hole is formed in the main semi-annular shell, a main mounting port communicated with the main annular pipeline hole is formed in the side surface of the main longitudinal supporting rod, a main longitudinal discharge pipeline hole communicated with one end of the main annular pipeline hole is formed in the main longitudinal discharge pipeline, a main mounting hole is formed in one end of the outer side of the auxiliary semi-annular shell, the main longitudinal discharge pipeline is mounted in the main mounting hole through a longitudinal limiting type component rotating connection mechanism, an auxiliary annular pipeline hole communicated with the bottom end of the main mounting hole is formed in the auxiliary semi-annular shell, the inner side of the auxiliary semi-annular shell, which is positioned in the auxiliary annular pipeline hole, is provided with a plurality of annular array-type and two groups of parallel turbine installation spaces, the central line of each turbine installation space faces the virtual circle center of the auxiliary semi-annular shell, the auxiliary annular pipeline hole is communicated with the circumferential surface of each turbine installation space through a main first vent hole, the exhaust port of the circumferential surface of each turbine installation space is communicated with the inner surface of the auxiliary semi-annular shell through a main second vent hole, a wind power cut-in turbine driving mechanism is installed in each turbine installation space, a main rotating shaft is installed at the end part of a rotating shaft of each wind power cut-in turbine driving mechanism, the rotating shaft penetrates through the inner side of the auxiliary semi-annular shell and extends to the external space on the inner side of the auxiliary semi-annular shell, and one end of each main rotating shaft, which is positioned outside, is provided with a cutting tool bit, and the middle part of the blade in the cutting tool bit and the central line of the exhaust port of the main second ventilation hole are positioned on the same straight line, and the straight line faces to the virtual circle center of the auxiliary semi-annular shell.

Furthermore, the longitudinal limiting type part rotary connecting mechanism comprises a hollow shell for the longitudinal limiting type part rotary connecting mechanism, an installation space for the longitudinal limiting type part rotary connecting mechanism, a bearing for the longitudinal limiting type part rotary connecting mechanism, a limiting plate structure for the longitudinal limiting type part rotary connecting mechanism, an I-shaped clamping plate for the longitudinal limiting type part rotary connecting mechanism, an air vent for the longitudinal limiting type part rotary connecting mechanism and a sealing ring for the longitudinal limiting type part rotary connecting mechanism; vertical spacing formula part is hollow shell for swivelling joint mechanism inside is equipped with the vertical spacing formula part mounting space for swivelling joint mechanism of no end formula, vertical spacing formula part for swivelling joint mechanism solid position on hollow shell top is run through by main vertical discharge line, and both run through the position and connect through vertical spacing formula part for swivelling joint mechanism bearing, vertical spacing formula part for swivelling joint mechanism hollow shell is lieing in vertical spacing formula part for swivelling joint mechanism mounting space's middle part is equipped with the vertical spacing formula part for swivelling joint mechanism limiting plate structure of integral type structure, vertical spacing formula part for swivelling joint mechanism mounting place for the limiting plate structure between the upper and lower surface vertical spacing formula part for swivelling joint mechanism uses the H-shaped joint board, vertical spacing formula part for swivelling joint mechanism the center of H-shaped joint board is equipped with the vertical spacing formula part for swivelling joint mechanism that communicates its both ends face and uses logical card board The gas pocket, just inside the top of vertical spacing formula part for swivelling joint mechanism worker font joint plate was installed to the bottom of main vertical delivery pipe, the side-mounting of vertical spacing formula part for swivelling joint mechanism worker font joint plate has vertical spacing formula part for swivelling joint mechanism bearing and vertical spacing formula part for swivelling joint mechanism sealing washer.

Further, the longitudinal limiting type part rotary connecting mechanism is communicated with the main longitudinal discharge pipeline hole through a vent hole.

Furthermore, the outer side of the hollow shell for the longitudinal limiting type part rotary connecting mechanism is fixed in the main mounting hole, and a sealing ring is mounted at the fixed position.

Further, the wind-driven cut-in turbine driving mechanism comprises a hollow shell for the wind-driven cut-in turbine driving mechanism, a cylindrical space for the wind-driven cut-in turbine driving mechanism, a rotating shaft for the wind-driven cut-in turbine driving mechanism, a turbine for the wind-driven cut-in turbine driving mechanism, an air inlet hole for the wind-driven cut-in turbine driving mechanism and an air outlet hole for the wind-driven cut-in turbine driving mechanism; the wind power cut-in type turbine driving mechanism is characterized in that a cylindrical space for the wind power cut-in type turbine driving mechanism is arranged at the center inside a hollow shell of the wind power cut-in type turbine driving mechanism, a rotating shaft for the wind power cut-in type turbine driving mechanism is installed at the center of the two end faces of the hollow shell of the wind power cut-in type turbine driving mechanism, a turbine for the wind power cut-in type turbine driving mechanism is installed on a shaft body located inside the cylindrical space for the wind power cut-in type turbine driving mechanism through the rotating shaft for the wind power cut-in type turbine driving mechanism, and two air inlets for the wind power cut-in type turbine driving mechanism and two air outlets for the wind power cut-in type turbine driving mechanism, which are communicated with the external space and the cylindrical space for the wind power cut-in type turbine driving mechanism, are formed in the side face of the hollow shell of the wind power cut-in type turbine driving mechanism.

Furthermore, the air inlet hole for the wind power cut-in turbine driving mechanism and the air outlet hole for the wind power cut-in turbine driving mechanism are communicated with the cylindrical space for the wind power cut-in turbine driving mechanism in a mode of being tangent to the side surface of the cylindrical space for the wind power cut-in turbine driving mechanism.

Furthermore, the wind-force cut-in turbine driving mechanism is installed in the turbine installation space by using a hollow shell, and the air inlet hole and the air outlet hole are respectively communicated with the main first vent hole and the main second vent hole.

Further, in the two groups of turbine installation spaces, the edge of one group of connected cutting heads extends out of the side surface of the auxiliary semi-annular shell, and the edge of the other group of connected cutting heads does not extend out of the side surface of the auxiliary semi-annular shell.

Further, during operation, the rotation direction of the auxiliary semi-annular shell rotates towards the direction that the edge of the cutting head extends out of the auxiliary semi-annular shell.

Compared with the prior art, the invention has the beneficial effects that: the invention utilizes the kinetic energy generated by high-pressure air to drive each rotary blade to rotate, and can blow and clean the surface of the trimmed fallen leaves, thereby improving the utilization rate of the kinetic energy.

Drawings

FIG. 1 is a schematic diagram of a full-section of a spherical trimmer for spherical plants according to the present invention;

FIG. 2 is a schematic view of the inner surface of the annular housing of the spherical trimmer for spherical plants according to the present invention in an extended state;

FIG. 3 is a schematic structural view of a longitudinal position-limiting type part rotating connection mechanism in the spherical trimmer for spherical plants according to the present invention;

FIG. 4 is a schematic structural diagram of a power cut-in turbine driving mechanism in a spherical trimmer for spherical plants according to the present invention;

in the figure: 1, bottom mounting base plate, 2, mounting plate, 3, main longitudinal support rod, 4, main semi-annular housing, 5, main longitudinal discharge pipe, 6, main mounting port, 7, main annular pipe hole, 8, main longitudinal discharge pipe hole, 9, sub semi-annular housing, 10, sub-annular pipe hole, 11, main mounting hole, 12, longitudinal position-limiting type part rotary connecting mechanism, 121, hollow housing for longitudinal position-limiting type part rotary connecting mechanism, 122, mounting space for longitudinal position-limiting type part rotary connecting mechanism, 123, bearing for longitudinal position-limiting type part rotary connecting mechanism, 124, limiting plate structure for longitudinal position-limiting type part rotary connecting mechanism, 125, clip plate for longitudinal position-limiting type part rotary connecting mechanism, 127, vent hole for longitudinal position-limiting type part rotary connecting mechanism, 128, seal ring for longitudinal position-limiting type part rotary connecting mechanism, 6, 13, a turbine installation space, 14, main first vents, 15, main second vents, 16, wind-driven turbine driving mechanisms, 161, hollow housings for wind-driven turbine driving mechanisms, 162, columnar spaces for wind-driven turbine driving mechanisms, 163, rotating shafts for wind-driven turbine driving mechanisms, 164, turbines for wind-driven turbine driving mechanisms, 165, air intake holes for wind-driven turbine driving mechanisms, 166, air exhaust holes for wind-driven turbine driving mechanisms, 17, rotating shafts, 18, and cutter heads.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, an embodiment of the present invention: comprises a bottom mounting base plate 1 and an auxiliary semi-annular shell 9, wherein the upper surface of the bottom mounting base plate 1 is provided with a mounting plate 2 and a main longitudinal support rod 3, the top of the main longitudinal support rod 3 is provided with a main semi-annular shell 4 with an integrated structure, the bottom of the top end of the main semi-annular shell 4 is provided with a main longitudinal discharge pipeline 5 with an integrated structure, the inside of the main semi-annular shell 4 is provided with a main annular pipeline hole 7, the side surface of the main longitudinal support rod 3 is provided with a main mounting port 6 communicated with the main annular pipeline hole 7, the inside of the main longitudinal discharge pipeline 5 is provided with a main longitudinal discharge pipeline hole 8 communicated with one end of the main annular pipeline hole 7, the outer end of the auxiliary semi-annular shell 9 is provided with a main mounting hole 11, the main longitudinal discharge pipeline 5 is mounted in the main mounting hole 11 through a longitudinal limiting type component rotary connecting mechanism 12, the inside of the auxiliary semi-annular shell 9 is provided with an auxiliary annular pipeline hole 10 communicated with the bottom end of the main mounting hole 11, a plurality of annular array-type and side-by-side two groups of turbine installation spaces 13 are arranged inside the auxiliary semi-annular casing 9 and are positioned on the inner side of the auxiliary semi-annular pipeline hole 10, the center line of each turbine installation space 13 faces the virtual circle center of the auxiliary semi-annular casing 9, the auxiliary annular pipeline hole 10 is communicated with the circumferential surface of each turbine installation space 13 through a main first vent hole 14, an exhaust port of the circumferential surface of each turbine installation space 13 is communicated with the inner surface of the auxiliary semi-annular casing 9 through a main second vent hole 15, a wind power cut-in turbine driving mechanism 16 is arranged inside each turbine installation space 13, a main rotating shaft 17 is arranged at the end part of a rotating shaft of each wind power cut-in turbine driving mechanism 16, and the rotating shaft 17 penetrates through the inner side of the auxiliary semi-annular casing 9 and extends to the outer space on the inner side of the auxiliary semi-annular casing 9, and a cutting tool bit 18 is arranged at one end of each main rotating shaft 17 positioned at the outside, the middle parts of blades in the cutting tool bits 18 and the central line of the exhaust port of the main second ventilation hole 15 are positioned on the same straight line, and the straight line faces to the virtual circle center of the auxiliary semi-annular shell 9.

Referring to fig. 2, the longitudinal position-limiting type part rotating connecting mechanism 12 includes a hollow housing 121 for the longitudinal position-limiting type part rotating connecting mechanism, an installation space 122 for the longitudinal position-limiting type part rotating connecting mechanism, a bearing 123 for the longitudinal position-limiting type part rotating connecting mechanism, a position-limiting plate structure 124 for the longitudinal position-limiting type part rotating connecting mechanism, an i-shaped snap plate 125 for the longitudinal position-limiting type part rotating connecting mechanism, an air vent 127 for the longitudinal position-limiting type part rotating connecting mechanism, and a sealing ring 128 for the longitudinal position-limiting type part rotating connecting mechanism; vertical spacing formula part is hollow shell 121 for swivelling joint mechanism is inside to be equipped with the vertical spacing formula part of no end formula mounting space 122 for swivelling joint mechanism, vertical spacing formula part for swivelling joint mechanism solid position on hollow shell 121 top is run through by main vertical discharge pipe way 5, and both run through the position and connect through vertical spacing formula part for swivelling joint mechanism bearing 123, vertical spacing formula part for swivelling joint mechanism hollow shell 121 is lieing in vertical spacing formula part for swivelling joint mechanism mounting space 122's middle part is equipped with the vertical spacing formula part for swivelling joint mechanism limiting plate structure 124 of integral type structure, vertical spacing formula part for swivelling joint mechanism mounting place for swivelling joint mechanism uses font chucking plate 125 between the upper and lower surface of vertical spacing formula part for swivelling joint mechanism limiting plate structure 124, vertical spacing formula part for swivelling joint mechanism uses font chucking plate 125's center is equipped with the vertical spacing of its both ends face of intercommunication The bottom end of the main longitudinal discharge pipe 5 is mounted inside the top end of the H-shaped clamping plate 125 for the longitudinal limiting type component rotary connecting mechanism, and the side surface of the H-shaped clamping plate 125 for the longitudinal limiting type component rotary connecting mechanism is provided with a bearing 123 for the longitudinal limiting type component rotary connecting mechanism and a sealing ring 128 for the longitudinal limiting type component rotary connecting mechanism; the longitudinal position-limiting type part rotary connecting mechanism is communicated with the main longitudinal discharge pipeline hole 8 through a vent hole 127; the outer side of the hollow housing 121 for the longitudinal position-limiting type component rotary connection mechanism is fixed inside the main mounting hole 11, and a seal ring is mounted at the fixed position.

Referring to fig. 3, the wind-driven plunge turbine drive mechanism 16 includes a hollow housing 161 for the wind-driven plunge turbine drive mechanism, a cylindrical space 162 for the wind-driven plunge turbine drive mechanism, a rotating shaft 163 for the wind-driven plunge turbine drive mechanism, a turbine 164 for the wind-driven plunge turbine drive mechanism, an air intake hole 165 for the wind-driven plunge turbine drive mechanism, and an air exhaust hole 166 for the wind-driven plunge turbine drive mechanism; a cylindrical space 162 for the wind-driven plunge turbine driving mechanism is arranged at the center inside the hollow shell 161 for the wind-driven plunge turbine driving mechanism, a rotating shaft 163 for the wind-driven plunge turbine driving mechanism is installed at the center of two end faces of the hollow shell 161 for the wind-driven plunge turbine driving mechanism, a turbine 164 for the wind-driven plunge turbine driving mechanism is installed on a shaft body positioned inside the cylindrical space 162 for the wind-driven plunge turbine driving mechanism by the rotating shaft 163 for the wind-driven plunge turbine driving mechanism, and two air inlet holes 165 for the wind-driven plunge turbine driving mechanism and an air outlet hole 166 for the wind-driven plunge turbine driving mechanism, which are communicated with the external space and the cylindrical space 162 for the wind-driven plunge turbine driving mechanism, are arranged on the side face of the hollow shell 161 for the wind-driven plunge turbine driving mechanism; the air inlet hole 165 and the air outlet hole 166 for the wind-force cut-in turbine driving mechanism are communicated with the cylindrical space 162 for the wind-force cut-in turbine driving mechanism in a manner of being tangent to the side surface of the cylindrical space 162 for the wind-force cut-in turbine driving mechanism; the hollow housing 161 for the wind-force cut-in turbine driving mechanism is installed inside the turbine installation space 13, and the air inlet hole 165 for the wind-force cut-in turbine driving mechanism and the air outlet hole 166 for the wind-force cut-in turbine driving mechanism are respectively communicated with the main first vent hole 14 and the main second vent hole 15; in the two groups of turbine installation spaces 13, the edge of one group of connected cutting heads 18 extends out of the side surface of the auxiliary semi-annular shell 9, and the edge of the other group of connected cutting heads 18 does not extend out of the side surface of the auxiliary semi-annular shell 9; in operation, the direction of rotation of the secondary semi-annular housing 9 is rotated in a direction in which the edge of the cutting head 18 protrudes out of the secondary semi-annular housing 9.

The specific use mode is as follows: in the invention, an air compressor is arranged on the upper surface of a mounting plate 2, then an exhaust pipeline of the air compressor is butted with a main butt joint port 6, when the air compressor works, high-pressure gas enters the interior of a longitudinal position-limiting type component rotating connecting mechanism 12 through each vent hole and further enters the interior of a wind power cut-in type vortex driving mechanism 16, due to the structural characteristics of the wind power cut-in type vortex driving mechanism 16, a rotating action can be generated on a cutting blade 18 to drive the cutting blade 18 to rotate, meanwhile, when the air is exhausted outside, because the cutting blade 18 is of a fan blade structure and one side of the cutting blade is provided with a component with a tip structure, the cutting blade 18 can be further driven to rotate, at the moment, the annular shell 9 is rotationally pushed, the omni-directional trimming can be carried out, and in the trimming process, the exhausted air can blow the trimmed fallen leaves, the effect of pruning is improved.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (9)

1. The utility model provides a spherical clipping machine for globular plant, includes bottom mounting substrate (1) and vice semi-annular shell (9), its characterized in that: the upper surface of the bottom mounting base plate (1) is provided with a mounting plate (2) and a main longitudinal support rod (3), the top of the main longitudinal support rod (3) is provided with a main semi-annular shell (4) of an integrated structure, the top bottom of the main semi-annular shell (4) is provided with a main longitudinal discharge pipeline (5) of the integrated structure, the inside of the main semi-annular shell (4) is provided with a main annular pipeline hole (7), the side surface of the main longitudinal support rod (3) is provided with a main mounting port (6) communicated with the main annular pipeline hole (7), the inside of the main longitudinal discharge pipeline (5) is provided with a main longitudinal discharge pipeline hole (8) communicated with one end of the main annular pipeline hole (7), the outer end of the auxiliary semi-annular shell (9) is provided with a main mounting hole (11), and the main longitudinal discharge pipeline (5) is mounted inside the main mounting hole (11) through a longitudinal limiting type component rotary connecting mechanism (12), the inside of vice semi-annular shell (9) is equipped with the vice ring type pipeline hole (10) of intercommunication main mounting hole (11) bottom, the inside of vice semi-annular shell (9) is lieing in the inboard of vice ring type pipeline hole (10) is equipped with a plurality of annular array, and two sets of turbine installation space (13) side by side, and every the central line of turbine installation space (13) all is towards the virtual centre of a circle department of vice semi-annular shell (9), vice ring type pipeline hole (10) and every the periphery of turbine installation space (13) all communicates through a main first air vent (14), every communicate through main second air vent (15) between the exhaust port of the periphery of turbine installation space (13) and vice semi-annular shell (9) internal surface, every the internally mounted of turbine installation space (13) one cut-in wind-type turbine actuating mechanism (16), every rotation axis tip installation one main rotation axis (17) of wind-force cut-in turbine actuating mechanism (16), just rotation axis (17) run through vice semi-annular shell (9) inboard, and extend to the external space of vice semi-annular shell (9) inboard, every a cutting tool bit (18) is all installed in the one end that lies in the outside to main rotation axis (17), just the middle part of blade is in the same straight line with the central line of main second ventilation hole (15) exhaust port in cutting tool bit (18), and this straight line is towards the virtual centre of a circle department of vice semi-annular shell (9).

2. The spherical trimmer according to claim 1, wherein: the longitudinal limiting type part rotating connecting mechanism (12) comprises a hollow shell (121) for the longitudinal limiting type part rotating connecting mechanism, an installation space (122) for the longitudinal limiting type part rotating connecting mechanism, a bearing (123) for the longitudinal limiting type part rotating connecting mechanism, a limiting plate structure (124) for the longitudinal limiting type part rotating connecting mechanism, an I-shaped clamping and connecting plate (125) for the longitudinal limiting type part rotating connecting mechanism, an air vent (127) for the longitudinal limiting type part rotating connecting mechanism and a sealing ring (128) for the longitudinal limiting type part rotating connecting mechanism; the hollow shell (121) for the longitudinal limiting type part rotary connecting mechanism is internally provided with a bottomless longitudinal limiting type part rotary connecting mechanism installation space (122), the solid part at the top end of the hollow shell (121) for the longitudinal limiting type part rotary connecting mechanism is penetrated by a main longitudinal discharge pipeline (5), the longitudinal limiting type part rotary connecting mechanism and the main longitudinal discharge pipeline are connected through a bearing (123) for the longitudinal limiting type part rotary connecting mechanism at the penetrating part, the hollow shell (121) for the longitudinal limiting type part rotary connecting mechanism is arranged in the middle of the longitudinal limiting type part rotary connecting mechanism installation space (122) and is provided with a limiting plate structure (124) for the longitudinal limiting type part rotary connecting mechanism with an integrated structure, a longitudinal limiting type part rotary connecting mechanism I-shaped clamping plate (125) for the longitudinal limiting type part rotary connecting mechanism is arranged between the upper surface and the lower surface of the limiting plate structure (124) for the longitudinal limiting type part rotary connecting mechanism, the center of vertical spacing formula part swivelling joint mechanism uses I-shaped joint board (125) is equipped with vertical spacing formula part swivelling joint mechanism of its both ends face of intercommunication and uses air vent (127), just the bottom of main vertical discharge pipe way (5) is installed inside the top of vertical spacing formula part swivelling joint mechanism uses I-shaped joint board (125), the side-mounting of vertical spacing formula part swivelling joint mechanism uses I-shaped joint board (125) has vertical spacing formula part swivelling joint mechanism to use bearing (123) and vertical spacing formula part swivelling joint mechanism to use sealing washer (128).

3. The spherical trimmer according to claim 2, wherein: the longitudinal position-limiting type part rotary connecting mechanism is communicated with the main longitudinal discharge pipeline hole (8) through a vent hole (127).

4. The spherical trimmer according to claim 2, wherein: the outer side of the hollow shell (121) for the longitudinal limiting type part rotary connecting mechanism is fixed in the main mounting hole (11), and a sealing ring is mounted at the fixed position.

5. The spherical trimmer according to claim 1, wherein: the wind-driven cut-in turbine driving mechanism (16) comprises a hollow shell (161) for the wind-driven cut-in turbine driving mechanism, a cylindrical space (162) for the wind-driven cut-in turbine driving mechanism, a rotating shaft (163) for the wind-driven cut-in turbine driving mechanism, a turbine (164) for the wind-driven cut-in turbine driving mechanism, an air inlet hole (165) for the wind-driven cut-in turbine driving mechanism and an air outlet hole (166) for the wind-driven cut-in turbine driving mechanism; the center inside the hollow shell (161) for the wind power cut-in turbine driving mechanism is provided with a cylindrical space (162) for the wind power cut-in turbine driving mechanism, a rotating shaft (163) for the wind-force cut-in turbine driving mechanism is arranged at the center of two end faces of the hollow shell (161) for the wind-force cut-in turbine driving mechanism, the rotating shaft (163) for the wind-driven turbine driving mechanism is provided with a turbine (164) for the wind-driven turbine driving mechanism mounted on a shaft body located in a cylindrical space (162) for the wind-driven turbine driving mechanism, and two air inlets (165) and air outlets (166) for the wind-driven cut-in turbine driving mechanism, which are communicated with the external space and the cylindrical space (162) for the wind-driven cut-in turbine driving mechanism, are arranged on the side surface of the hollow shell (161) for the wind-driven cut-in turbine driving mechanism.

6. The spherical trimmer according to claim 5, wherein: the air inlet hole (165) and the air outlet hole (166) are communicated with the cylindrical space (162) in a mode of being tangent to the side surface of the cylindrical space (162) for the wind-driven cut-in turbine driving mechanism.

7. The spherical trimmer according to claim 5, wherein: the wind power cut-in type turbine driving mechanism is characterized in that a hollow shell (161) is arranged in a turbine installation space (13), and an air inlet hole (165) and an air outlet hole (166) for the wind power cut-in type turbine driving mechanism are respectively communicated with a main first vent hole (14) and a main second vent hole (15).

8. The spherical trimmer according to claim 1, wherein: in the two groups of turbine installation spaces (13), the edge of one group of connected cutting heads (18) extends out of the side surface of the auxiliary semi-annular shell (9), and the edge of the other group of connected cutting heads (18) does not extend out of the side surface of the auxiliary semi-annular shell (9).

9. The spherical trimmer according to claim 8, wherein: when the cutting tool works, the rotating direction of the auxiliary semi-annular shell (9) rotates towards the direction that the edge of the cutting tool bit (18) extends out of the auxiliary semi-annular shell (9).

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