CN112189471B

CN112189471B - Biotechnology service terminal

Info

Publication number: CN112189471B
Application number: CN202011089143.6A
Authority: CN
Inventors: 李美芳
Original assignee: Guangzhou Kewei Biotechnology Co ltd
Current assignee: Guangzhou Kewei Biotechnology Co ltd
Priority date: 2020-10-13
Filing date: 2020-10-13
Publication date: 2021-07-23
Anticipated expiration: 2040-10-13
Also published as: CN112189471A

Abstract

The invention discloses a biotechnology service terminal which comprises a base, wherein a splitting mechanism for splitting branches is arranged on the upper right side of the base, a clamping mechanism for clamping and fixing the branches is arranged on the upper left side of the base, a shearing mechanism for shearing the branches is further arranged on the upper left side of the base, the device can automatically clamp and fix the branches to be grafted so as to ensure the accuracy of cutting and splitting the branches, the power supply of a cutting knife can be automatically connected after the branches are clamped, the branches are cut in an energy-saving manner, the cut branches can be immediately split by a splitting knife, the integrated operation of cutting and splitting the branches is realized, the efficiency of grafting the branches is greatly improved, the resetting of the whole device can be realized by turning off a motor after the operation is finished, and the operation convenience is higher.

Description

Biotechnology service terminal

Technical Field

The invention relates to the field of biotechnology, in particular to a biotechnology service terminal.

Background

Grafting, which is one of artificial propagation methods of plants, is to graft a branch or bud of one plant onto a stem or root of another plant, the stem of the plant is cut and split, so that a branch bud of another plant is grafted onto the split plant.

At the present stage, when plants are grafted, most of the plants are cut off through the manual handheld instrument, and the plant stem cutting surface is split through the instrument again, so that not only is the grafting efficiency lower, but also the operation difficulty is higher when the plant stems are cut off and split.

Disclosure of Invention

The invention aims to provide a biotechnology service terminal, which solves the problem that plant stems cannot be cut and split synchronously and automatically.

The invention is realized by the following technical scheme.

The biotechnological service terminal comprises a base, wherein a splitting mechanism for splitting branches is arranged on the upper right side of the base, a clamping mechanism for clamping and fixing the branches is arranged on the upper left side of the base, a shearing mechanism for shearing the branches is further arranged on the upper left side of the base, the splitting mechanism comprises a transmission cavity positioned in the base, a fixed block is fixed on the upper right end face in the base, a clamping cavity with a leftward opening is arranged at the left end in the fixed block, a moving cavity with a leftward opening is arranged in the right inner wall of the clamping cavity, a moving plate capable of moving left and right is arranged in the moving cavity, a moving cavity with a leftward opening is arranged in the moving plate, a moving block capable of moving up and down is arranged at the upper end in the moving cavity, an elastic spring is connected between the lower end face of the moving block and the lower inner wall of the moving cavity, and a splitting knife positioned in the clamping cavity is fixed on the left end face of the moving block, two elastic springs are connected between the right end face of the movable plate and the right inner wall of the movable cavity, a driving cavity is arranged in the right inner wall at the upper end of the movable cavity, a rotating shaft is rotated between the upper inner wall of the driving cavity and the lower inner wall of the transmission cavity, a first sector gear positioned in the driving cavity is arranged at the upper end of the rotating shaft, a moving rod with the right end extending into the driving cavity and positioned at the front side of the first sector gear is fixed on the right end face at the upper end of the movable plate, a rack capable of being meshed with the first sector gear is arranged at the rear end in the moving rod, a driven gear positioned in the transmission cavity is arranged at the lower end of the rotating shaft, a first motor is arranged in the lower inner wall in the middle of the transmission cavity, a transmission shaft is dynamically connected to the upper end of the first motor, a transmission gear capable of being meshed with the driven gear is arranged at the upper end of the transmission shaft, a first driven cavity is arranged in the upper inner wall at the right end of the transmission cavity, the right side of the first driven cavity is provided with a second driven cavity with a downward opening, a rotating rod is arranged on the left inner wall of the second driven cavity in a rotating mode, a driven bevel gear located in the second driven cavity is arranged at the right end of the rotating rod, a spline cavity with a leftward opening is arranged at the left end of the rotating rod, an extensible shaft capable of stretching into the spline cavity from left to right and extending into the left end of the spline cavity is arranged in the spline cavity, a chain wheel is arranged at the left end of the extensible shaft, and a chain rope with one end connected with the end face of the displacement block is wound on the chain wheel.

Preferably, a sliding bevel gear located in the second driven cavity is connected to the lower end of the rotating shaft in a sliding mode through a spline, a slider cavity with an upward opening is formed in the sliding bevel gear, a slider capable of sliding in the slider cavity is arranged in the slider cavity, two connecting springs are connected between the upper end face of the slider and the upper inner wall of the second driven cavity, and a rope is connected between the upper end face of the slider and the lower end face of the right end of the moving rod.

Preferably, the clamping mechanism comprises a rotating shaft which rotates on the upper inner wall and the lower inner wall of the left end of the transmission cavity, a torsion spring is connected between the lower end of the rotating shaft and the lower inner wall of the transmission cavity, a second sector gear which can be meshed with the transmission gear is arranged at the upper end of the rotating shaft, a connecting rod of which the upper end extends into the external space is fixed at the left end of the second sector gear, a rotating block is fixed on the upper end face of the connecting rod, a compression cavity with a right opening is arranged at the right end of the rotating block, a clamping block which can move left and right is arranged in the compression cavity, a clamping groove with a right opening is arranged in the clamping block, two compression springs are connected between the left end face of the clamping block and the left inner wall of the compression cavity, a triangular clamping plate which can move left and right is arranged in the clamping cavity, a triangular groove with a left opening is arranged in the triangular clamping plate, and two extension springs are connected between the right end face of the triangular clamping plate and the right inner wall of the clamping cavity, the upper end of the triangular clamping plate is provided with a cutting groove with an opening communicated with the clamping cavity towards the left and the right, a sliding knife groove communicated with the left and the right is arranged in the lower inner wall of the cutting groove, and the left end of the splitting knife extends into the sliding knife groove and is positioned at the lower side of the cutting groove.

Preferably, cut off the mechanism including fixing the battery piece of the left end in the clamp block, the battery piece can control elastic motion in the clamp block, be fixed with on the left inner wall of compression chamber and be located the left circular telegram piece of battery piece, the turning block upper end is equipped with the right cutting chamber of opening, be equipped with the second motor in the inner wall under the cutting chamber, second motor upper end power is connected with the cutting axle, the epaxial position that is equipped with of cutting is in the cutting knife that external space was stretched into to cutting intracavity and right-hand member, the second motor with the electricity is connected with the electric wire between the circular telegram piece.

Preferably, the front end in the base is provided with a handheld cavity communicated up and down, and the equipment can be handheld through the handheld cavity.

The invention has the beneficial effects that: the branch that this equipment can treat the grafting carries out self-holding and fixes to the assurance is cut the accuracy with the split to the branch, can the automatic connection cutting knife power and carry out energy-conserving cutting to the branch after pressing from both sides tight branch, the branch after cutting can be carried out the split by the split sword immediately, realized cutting the branch and the integrated operation of split, improved the efficiency of grafting branch greatly, the operation finishes the back and closes the motor alright realize resetting of whole equipment, higher convenient operation nature has.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is a schematic structural diagram at A-A in FIG. 1 according to an embodiment of the present invention;

FIG. 3 is a schematic structural diagram at B-B in FIG. 1 according to an embodiment of the present invention;

FIG. 4 is a schematic structural diagram at C-C in FIG. 1 according to an embodiment of the present invention;

fig. 5 is a schematic structural diagram at D in fig. 1 according to an embodiment of the present invention.

Detailed Description

The invention will now be described in detail with reference to fig. 1-5, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The biotech service terminal described in conjunction with fig. 1-5 comprises a base 10, a splitting mechanism 69 for splitting branches is disposed on the upper right side of the base 10, a clamping mechanism 67 for clamping and fixing branches is disposed on the upper left side of the base 10, a cutting mechanism 68 for cutting branches is further disposed on the upper left side of the base 10, the splitting mechanism 69 includes a transmission cavity 11 located in the base 10, a fixed block 35 is fixed on the upper right end face in the base 10, a clamping cavity 28 with a leftward opening is disposed at the left end in the fixed block 35, a moving cavity 38 with a leftward opening is disposed in the right inner wall of the clamping cavity 28, a moving plate 34 with a leftward opening is disposed in the moving plate 34, a moving block 30 with a leftward opening is disposed at the upper end in the moving cavity 29, an elastic spring 37 is connected between the lower end face of the moving block 30 and the lower inner wall of the moving cavity 29, a cleaver 31 positioned in the clamping cavity 28 is fixed on the left end face of the displacement block 30, two elastic springs 36 are connected between the right end face of the moving plate 34 and the right inner wall of the moving cavity 38, a driving cavity 64 is arranged in the right inner wall of the upper end of the moving cavity 38, a rotating shaft 41 is rotatably arranged between the upper inner wall of the driving cavity 64 and the lower inner wall of the transmission cavity 11, a first sector gear 63 positioned in the driving cavity 64 is arranged at the upper end of the rotating shaft 41, a moving rod 62 with the right end extending into the driving cavity 64 and positioned in front of the first sector gear 63 is fixed on the right end face of the upper end of the moving plate 34, a rack 50 capable of meshing with the first sector gear 63 is arranged at the rear end in the moving rod 62, a driven gear 40 positioned in the transmission cavity 11 is arranged at the lower end of the rotating shaft 41, and a first motor 44 is arranged in the lower inner wall in the middle of the transmission cavity 11, the upper end of the first motor 44 is in power connection with a transmission shaft 43, the upper end of the transmission shaft 43 is provided with a transmission gear 45 which can be meshed with the driven gear 40, the upper inner wall of the right end of the transmission cavity 11 is internally provided with a first driven cavity 25, the right side of the first driven cavity 25 is provided with a second driven cavity 57 with a downward opening, the left inner wall of the second driven cavity 57 is rotatably provided with a rotating rod 51, the right end of the rotating rod 51 is provided with a driven bevel gear 58 which is positioned in the second driven cavity 57, the left end of the rotating rod 51 is provided with a spline cavity 59 with a leftward opening, the spline cavity 59 is internally provided with a telescopic shaft 42 which can be stretched left and right in the spline cavity 59, the left end of the telescopic shaft 42 extends into the first driven cavity 25, the left end of the chain wheel 26 is provided with a chain rope 39, and one end of the chain rope is connected with the lower end face of the displacement block 30 in a winding mode.

Advantageously, a sliding bevel gear 56 located in the second driven cavity 57 is slidably connected to the lower end of the rotating shaft 41 through a spline, a slider cavity 54 with an upward opening is formed in the sliding bevel gear 56, a slider 55 capable of sliding in the slider cavity 54 is arranged in the slider cavity 54, two connecting springs 53 are connected between the upper end surface of the slider 55 and the upper inner wall of the second driven cavity 57, and a rope 52 is connected between the upper end surface of the slider 55 and the lower end surface of the right end of the moving rod 62.

Beneficially, the clamping mechanism 67 includes a rotating shaft 46 rotating on the upper and lower inner walls of the left end of the transmission cavity 11, a torsion spring 47 is connected between the lower end of the rotating shaft 46 and the lower inner wall of the transmission cavity 11, a second sector gear 48 capable of meshing with the transmission gear 45 is arranged at the upper end of the rotating shaft 46, a connecting rod 12 with the upper end extending into the external space is fixed at the left end of the second sector gear 48, a rotating block 18 is fixed on the upper end face of the connecting rod 12, a compression cavity 15 with a rightward opening is arranged at the right end of the rotating block 18, a clamping block 14 capable of moving left and right is arranged in the compression cavity 15, a clamping groove 24 with a rightward opening is arranged in the clamping block 14, two compression springs 13 are connected between the left end face of the clamping block 14 and the left inner wall of the compression cavity 15, a triangular clamping plate 27 capable of moving left and right is arranged in the clamping cavity 28, a triangular groove 61 with a leftward opening is arranged in the triangular clamping plate 27, two expansion springs 33 are connected between the right end face of the triangular clamping plate 27 and the right inner wall of the clamping cavity 28, the upper end of the triangular clamping plate 27 is provided with a cutting groove 32 with an opening communicated with the clamping cavity 28 leftwards and rightwards, a sliding knife groove communicated leftwards and rightwards is arranged in the lower inner wall of the cutting groove 32, and the left end of the split fork knife 31 extends into the sliding knife groove and is located on the lower side of the cutting groove 32.

Beneficially, shearing mechanism 68 is including fixing the battery piece 16 of the interior left end of tight piece 14 of clamp, battery piece 16 can press from both sides the interior elastic motion of controlling of tight piece 14, be fixed with on the inner wall of the left side of compression chamber 15 and be located the left circular telegram piece 17 of battery piece 16, turning block 18 upper end is equipped with opening right cutting chamber 21, be equipped with second motor 20 in the inner wall under the cutting chamber 21, second motor 20 upper end power connection has cutting axle 23, be equipped with on the cutting axle 23 and be located cutting chamber 21 is interior and the right-hand member stretches into external space's cutting knife 22, second motor 20 with it has electric wire 19 to electrically connect between the circular telegram piece 17.

Advantageously, a hand-held cavity 49 which is communicated with the upper part and the lower part is arranged at the front end in the base 10, and the equipment can be operated in a hand-held mode through the hand-held cavity 49.

In an initial state, the rotating shaft 46 is under the action of the elastic force of the torsion spring 47, the second sector gear 48 on the rotating shaft 46 is just at a critical position of meshing with the transmission gear 45, the rotating block 18 is positioned at the left side of the fixed block 35, the clamping block 14 is positioned at the right end in the compression cavity 15 under the action of the elastic force of the compression spring 13, the energizing block 17 is in a non-meshing state with the battery block 16, the moving plate 34 is positioned in the moving cavity 38 under the action of the elastic spring 36, the cleaver 31 and the displacement block 30 are positioned at the upper end in the displacement cavity 29 under the action of the elastic force of the elastic spring 37, the rope 52 is in a loose state, and the sliding bevel gear 56 is positioned at the upper side of the driven bevel gear 58 under the action of the connecting spring 53.

When the device is operated, only the hand-held cavity 49 is needed to be held by hand and the first motor 44 is started, the branch part to be grafted extends into the triangular groove 61 in the triangular clamping plate 27, the branch is abutted against the front inner wall and the rear inner wall of the triangular groove 61, the first motor 44 works to drive the transmission shaft 43 and the transmission gear 45 on the transmission shaft 43 to rotate, the transmission gear 45 rotates to drive the second sector gear 48 meshed with the transmission gear to rotate, so as to drive the connecting rod 12 and the rotating block 18 on the connecting rod 12 to rotate, the rotating block 18 rotates to drive the clamping block 14 to move rightwards and abut against the left end face of the branch positioned in the triangular groove 61, so as to clamp and fix the branch, when the battery block 16 is contacted with the electrifying block 17, the second motor 20 is electrified to start working, so as to drive the cutting shaft 23 and the cutting shaft 23 to rotate, the cutting knife 22 rotates to cut the upper end of the branch, when the cutting knife 22 cuts the upper end of the branch, the second sector gear 48 just rotates out of engagement with the transmission shaft 43, thus keeping the branches clamped by the clamping blocks 14 and the triangular clamping plates 27;

the transmission gear 45 rotates to drive the driven gear 40 engaged with the transmission gear to rotate, so as to drive the rotating shaft 41 and the sliding bevel gear 56 and the first sector gear 63 on the rotating shaft 41 to rotate, after the transmission gear 45 rotates to be disengaged from the second sector gear 48, the first sector gear 63 just rotates to be engaged with the rack 50 on the moving rod 62, the first sector gear 63 rotates to drive the moving rod 62 engaged with the first sector gear through the rack 50 to move leftwards, so as to drive the moving plate 34 and the splitting knife 31 on the moving plate 34 to move leftwards, the splitting knife 31 moves leftwards and is inserted into a vertical shearing position, the moving rod 62 moves leftwards to release the rope 52, at the moment, the first sector gear 63 rotates to be disengaged from the right end of the rack 50, the moving rod 62 stops moving leftwards continuously, so that the splitting knife 31 is positioned at the upper end in a tree branch, after the tensile force of the sliding bevel gear 56 and the rope 52 move downwards under the elastic force of the connecting spring 53 and the driven bevel gear 58 And meshing, the sliding bevel gear 56 rotates to drive the driven bevel gear 58 meshed with the sliding bevel gear to rotate, so as to drive the rotating rod 51 and the telescopic shaft 42 in the rotating rod 51 to rotate, the telescopic shaft 42 rotates to drive the chain wheel 26 to rotate, the chain wheel 26 rotates to wind the chain rope 39, the splitting knife 31 and the displacement block 30 move downwards under the tension of the chain rope 39 to split branches, the first motor 44 is turned off after splitting is finished, the rotating shaft 46 and the rotating block 18 are reversely reset under the action of the torsion spring 47, the splitting knife 31 and the displacement block 30 move upwards under the action of the elastic force of the elastic spring 37 to reset, the moving plate 34 moves rightwards under the tension of the elastic spring 36 to reset, the rope 52 is tensioned again, and the sliding bevel gear 56 moves upwards under the tension of the rope 52 to disengage from the driven bevel gear 58, so as to finish the resetting of the machine body.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims

1. A biotechnology service terminal, includes the base, its characterized in that: the upper right side of the base is provided with a splitting mechanism for splitting branches, the upper left side of the base is provided with a clamping mechanism for clamping and fixing the branches, the upper left side of the base is also provided with a cutting mechanism for cutting the branches, the splitting mechanism comprises a transmission cavity positioned in the base, a fixed block is fixed on the upper right end surface in the base, a clamping cavity with a leftward opening is arranged at the left end in the fixed block, a moving cavity with a leftward opening is arranged in the right inner wall of the clamping cavity, a moving plate capable of moving left and right is arranged in the moving cavity, a moving cavity with a leftward opening is arranged in the moving plate, a moving block capable of moving up and down is arranged at the upper end in the moving cavity, an elastic spring is connected between the lower end surface of the moving block and the lower inner wall of the moving cavity, a splitting knife positioned in the clamping cavity of the moving plate is fixed on the left end surface of the moving block, and two elastic springs are connected between the right end surface and the right inner wall of the moving cavity, a driving cavity is arranged in the right inner wall at the upper end of the moving cavity, a rotating shaft is rotated between the upper inner wall of the driving cavity and the lower inner wall of the transmission cavity, a first sector gear positioned in the driving cavity is arranged at the upper end of the rotating shaft, a moving rod is fixed on the right end surface at the upper end of the moving plate, the right end of the moving rod extends into the driving cavity and is positioned at the front side of the first sector gear, a rack capable of being meshed with the first sector gear is arranged at the rear end in the moving rod, a driven gear positioned in the transmission cavity is arranged at the lower end of the rotating shaft, a first motor is arranged in the lower inner wall in the middle of the transmission cavity, a transmission shaft is connected to the upper end of the first motor in a power mode, a transmission gear capable of being meshed with the driven gear is arranged at the upper end of the transmission shaft, a first driven cavity is arranged in the upper inner wall at the right end of the transmission cavity, a second driven cavity with a downward opening is arranged on the right side of the first driven cavity, the left inner wall of the second driven cavity is provided with a rotating rod in a rotating mode, the right end of the rotating rod is provided with a driven bevel gear located in the second driven cavity, the left end of the rotating rod is provided with a left-opened spline cavity, the spline cavity is internally provided with a telescopic shaft capable of stretching left and right in the spline cavity, the left end of the telescopic shaft stretches into the first driven cavity, the left end of the telescopic shaft is provided with a chain wheel, and the chain wheel is wound with a chain rope, one end of the chain rope is connected with the lower end face of the displacement block.

2. A biotech services terminal according to claim 1, characterized by: the lower end of the rotating shaft is in spline sliding connection with a sliding bevel gear located in the second driven cavity, a slider cavity with an upward opening is arranged in the sliding bevel gear, a slider capable of sliding in the slider cavity is arranged in the slider cavity, two connecting springs are connected between the upper end face of the slider and the upper inner wall of the second driven cavity, and a rope is connected between the upper end face of the slider and the lower end face of the right end of the moving rod.

3. A biotech services terminal according to claim 1, characterized by: the clamping mechanism comprises a rotating shaft which rotates on the upper inner wall and the lower inner wall of the left end of the transmission cavity, a torsion spring is connected between the lower end of the rotating shaft and the lower inner wall of the transmission cavity, a second sector gear which can be meshed with the transmission gear is arranged at the upper end of the rotating shaft, a connecting rod with the upper end extending into the external space is fixed at the left end of the second sector gear, a rotating block is fixed on the upper end face of the connecting rod, a compression cavity with a right opening is arranged at the right end of the rotating block, a clamping block which can move left and right is arranged in the compression cavity, a clamping groove with a right opening is arranged in the clamping block, two compression springs are connected between the left end face of the clamping block and the left inner wall of the compression cavity, a triangular clamping plate which can move left and right is arranged in the clamping cavity, a triangular groove with a left opening is arranged in the triangular clamping plate, and two extension springs are connected between the right end face of the triangular clamping plate and the right inner wall of the clamping cavity, the upper end of the triangular clamping plate is provided with a cutting groove with an opening communicated with the clamping cavity towards the left and the right, a sliding knife groove communicated with the left and the right is arranged in the lower inner wall of the cutting groove, and the left end of the splitting knife extends into the sliding knife groove and is positioned at the lower side of the cutting groove.

4. A biotech services terminal according to claim 3, characterized by: the utility model discloses a cutting mechanism, including fixing the battery piece of left end in the clamp block, the battery piece can control elastic motion in the clamp block, be fixed with on the left inner wall of compression chamber and be located the left circular telegram piece of battery piece, the turning block upper end is equipped with the opening cutting chamber to the right, be equipped with the second motor in the cutting intracavity lower wall, second motor upper end power is connected with the cutting axle, the epaxial position that is equipped with of cutting is in the cutting intracavity and right-hand member stretch into external space's cutting knife, the second motor with the electricity is connected with the electric wire between the circular telegram piece.

5. A biotech services terminal according to claim 3, characterized by: the front end is equipped with the handheld chamber of intercommunication from top to bottom in the base, through handheld chamber can carry out handheld operation to this equipment.